Your search keyword '"Bernd Bukau"' showing total 155 results

1. Molecular dissection of amyloid disaggregation by human HSP70

Author

Carolyn P. Schneider, Nadinath B. Nillegoda, Anne S. Wentink, Bernd Bukau, Paolo De Los Rios, Jennifer Feufel, Alessandro Barducci, Janosch Hennig, and Gabrielė Ubartaitė

Subjects

0301 basic medicine, Amyloid, Entropy, Protein aggregation, Fibril, Models, Biological, Protein Aggregation, Pathological, Inclusion bodies, Cellular protein, Protein Aggregates, 03 medical and health sciences, Adenosine Triphosphate, 0302 clinical medicine, medicine, Humans, HSP70 Heat-Shock Proteins, HSP110 Heat-Shock Proteins, Multidisciplinary, biology, Chemistry, Hydrolysis, Neurodegeneration, Parkinson Disease, HSP40 Heat-Shock Proteins, Amyloid fibril, medicine.disease, Hsp70, 030104 developmental biology, Chaperone (protein), alpha-Synuclein, Biophysics, biology.protein, 030217 neurology & neurosurgery

Abstract

The deposition of highly ordered fibrillar-type aggregates into inclusion bodies is a hallmark of neurodegenerative diseases such as Parkinson’s disease. The high stability of such amyloid fibril aggregates makes them challenging substrates for the cellular protein quality-control machinery1,2. However, the human HSP70 chaperone and its co-chaperones DNAJB1 and HSP110 can dissolve preformed fibrils of the Parkinson’s disease-linked presynaptic protein α-synuclein in vitro3,4. The underlying mechanisms of this unique activity remain poorly understood. Here we use biochemical tools and nuclear magnetic resonance spectroscopy to determine the crucial steps of the disaggregation process of amyloid fibrils. We find that DNAJB1 specifically recognizes the oligomeric form of α-synuclein via multivalent interactions, and selectively targets HSP70 to fibrils. HSP70 and DNAJB1 interact with the fibril through exposed, flexible amino and carboxy termini of α-synuclein rather than the amyloid core itself. The synergistic action of DNAJB1 and HSP110 strongly accelerates disaggregation by facilitating the loading of several HSP70 molecules in a densely packed arrangement at the fibril surface, which is ideal for the generation of ‘entropic pulling’ forces. The cooperation of DNAJB1 and HSP110 in amyloid disaggregation goes beyond the classical substrate targeting and recycling functions that are attributed to these HSP70 co-chaperones and constitutes an active and essential contribution to the remodelling of the amyloid substrate. These mechanistic insights into the essential prerequisites for amyloid disaggregation may provide a basis for new therapeutic interventions in neurodegeneration. The molecular steps that lead to the disaggregation of amyloid fibrils are shown to involve the synergistic action of HSP70 and its co-chaperones DNAJB1 and HSP110.

Published

2020

2. Cellular sequestrases maintain basal Hsp70 capacity ensuring balanced proteostasis

Author

Regina Zahn, Axel Mogk, Karsten Richter, Chi-Ting Ho, Areeb Jawed, Tomas Grousl, Bernd Bukau, Marije Semmelink, Oren Shatz, and Carmen Ruger-Herreros

Subjects

0301 basic medicine, Proteases, Saccharomyces cerevisiae Proteins, Amino Acid Transport Systems, Science, Saccharomyces cerevisiae, General Physics and Astronomy, Protein aggregation, Biochemistry, General Biochemistry, Genetics and Molecular Biology, Article, Protein Refolding, 03 medical and health sciences, 0302 clinical medicine, Chaperones, HSP70 Heat-Shock Proteins, lcsh:Science, Heat-Shock Proteins, Multidisciplinary, biology, Chemistry, General Chemistry, HSP40 Heat-Shock Proteins, biology.organism_classification, Cell biology, Hsp70, 030104 developmental biology, Proteostasis, Chaperone (protein), biology.protein, Protein folding, lcsh:Q, Protein quality, 030217 neurology & neurosurgery

Abstract

Maintenance of cellular proteostasis is achieved by a multi-layered quality control network, which counteracts the accumulation of misfolded proteins by refolding and degradation pathways. The organized sequestration of misfolded proteins, actively promoted by cellular sequestrases, represents a third strategy of quality control. Here we determine the role of sequestration within the proteostasis network in Saccharomyces cerevisiae and the mechanism by which it occurs. The Hsp42 and Btn2 sequestrases are functionally intertwined with the refolding activity of the Hsp70 system. Sequestration of misfolded proteins by Hsp42 and Btn2 prevents proteostasis collapse and viability loss in cells with limited Hsp70 capacity, likely by shielding Hsp70 from misfolded protein overload. Btn2 has chaperone and sequestrase activity and shares features with small heat shock proteins. During stress recovery Btn2 recruits the Hsp70-Hsp104 disaggregase by directly interacting with the Hsp70 co-chaperone Sis1, thereby shunting sequestered proteins to the refolding pathway., The sequestration of misfolded proteins into large assemblies by sequestrases is now considered as the third pillar in protein quality control besides chaperones and proteases. Here the authors characterise the functions of the sequestrases Hsp42 and Btn2 in the proteostasis network of S. cerevisiae and find that they protect cells from too exhaustive depletion of the Hsp70 system.

Published

2019

3. The Hsp70 chaperone network

Author

Rina Rosenzweig, Bernd Bukau, Matthias P. Mayer, and Nadinath B. Nillegoda

Subjects

Protein Folding, Protein domain, Protein aggregation, Chaperonin, Protein Aggregates, 03 medical and health sciences, 0302 clinical medicine, Protein Domains, Heat shock protein, Animals, Humans, HSP70 Heat-Shock Proteins, HSP90 Heat-Shock Proteins, Molecular Biology, 030304 developmental biology, Adenosine Triphosphatases, 0303 health sciences, biology, Chemistry, Cell Biology, Hsp90, Hsp70, Cell biology, Chaperone (protein), biology.protein, Protein folding, 030217 neurology & neurosurgery

Abstract

The 70-kDa heat shock proteins (Hsp70s) are ubiquitous molecular chaperones that act in a large variety of cellular protein folding and remodelling processes. They function virtually at all stages of the life of proteins from synthesis to degradation and are thus crucial for maintaining protein homeostasis, with direct implications for human health. A large set of co-chaperones comprising J-domain proteins and nucleotide exchange factors regulate the ATPase cycle of Hsp70s, which is allosterically coupled to substrate binding and release. Moreover, Hsp70s cooperate with other cellular chaperone systems including Hsp90, Hsp60 chaperonins, small heat shock proteins and Hsp100 AAA+ disaggregases, together constituting a dynamic and functionally versatile network for protein folding, unfolding, regulation, targeting, aggregation and disaggregation, as well as degradation. In this Review we describe recent advances that have increased our understanding of the molecular mechanisms and working principles of the Hsp70 network. This knowledge showcases how the Hsp70 chaperone system controls diverse cellular functions, and offers new opportunities for the development of chemical compounds that modulate disease-related Hsp70 activities. The Hsp70 chaperones regulate protein metabolism, including folding, unfolding, subcellular localization, aggregation/disaggregation and incorporation into protein complexes. Recent studies have revealed the mechanisms of functions of Hsp70s and their co-chaperones, highlighting new opportunities for modulating disease-related Hsp70 roles.

Published

2019

4. The Diverse Functions of Small Heat Shock Proteins in the Proteostasis Network

Author

Axel Mogk, Bernd Bukau, and Kevin Reinle

Subjects

Protein Folding, biology, Chemistry, Translation (biology), Protein aggregation, Stress Granules, Heat-Shock Proteins, Small, Cell biology, Hsp70, Protein Aggregates, Stress granule, Proteostasis, Structural Biology, Multiprotein Complexes, Chaperone (protein), biology.protein, Animals, Humans, Protein folding, Protein Multimerization, Binding site, Molecular Biology, Molecular Chaperones

Abstract

The protein quality control (PQC) system maintains protein homeostasis by counteracting the accumulation of misfolded protein conformers. Substrate degradation and refolding activities executed by ATP-dependent proteases and chaperones constitute major strategies of the proteostasis network. Small heat shock proteins represent ATP-independent chaperones that bind to misfolded proteins, preventing their uncontrolled aggregation. sHsps share the conserved α-crystallin domain (ACD) and gain functional specificity through variable and largely disordered N- and C-terminal extensions (NTE, CTE). They form large, polydisperse oligomers through multiple, weak interactions between NTE/CTEs and ACD dimers. Sequence variations of sHsps and the large variability of sHsp oligomers enable sHsps to fulfill diverse tasks in the PQC network. sHsp oligomers represent inactive yet dynamic resting states that are rapidly deoligomerized and activated upon stress conditions, releasing substrate binding sites in NTEs and ACDs Bound substrates are usually isolated in large sHsp/substrate complexes. This sequestration activity of sHsps represents a third strategy of the proteostasis network. Substrate sequestration reduces the burden for other PQC components during immediate and persistent stress conditions. Sequestered substrates can be released and directed towards refolding pathways by ATP-dependent Hsp70/Hsp100 chaperones or sorted for degradation by autophagic pathways. sHsps can also maintain the dynamic state of phase-separated stress granules (SGs), which store mRNA and translation factors, by reducing the accumulation of misfolded proteins inside SGs and preventing unfolding of SG components. This ensures SG disassembly and regain of translational capacity during recovery periods.

Published

2022

5. Chaperone-Mediated Protein Disaggregation Triggers Proteolytic Clearance of Intra-nuclear Protein Inclusions

Author

Lucas V. Cairo, Carmen Ruger-Herreros, Axel Mogk, Stefan Jentsch, Bernd Bukau, Fabian den Brave, and Chandhuru Jagadeesan

Subjects

0301 basic medicine, Proteasome Endopeptidase Complex, Protein Folding, Saccharomyces cerevisiae Proteins, Chaperone, Saccharomyces cerevisiae, Protein aggregation, Protein degradation, General Biochemistry, Genetics and Molecular Biology, Article, Hsp70, 03 medical and health sciences, Protein Aggregates, 0302 clinical medicine, Disaggregation, HSP70 Heat-Shock Proteins, Nuclear protein, HSP110 Heat-Shock Proteins, lcsh:QH301-705.5, Heat-Shock Proteins, Hsp40, biology, Chemistry, nucleus, Hsp110, Nuclear Proteins, HSP40 Heat-Shock Proteins, Apj1, Cell biology, Cytosol, 030104 developmental biology, Proteostasis, Proteasome, lcsh:Biology (General), Cytoplasm, Chaperone (protein), Proteolysis, biology.protein, protein degradation, 030217 neurology & neurosurgery

Abstract

Summary The formation of insoluble inclusions in the cytosol and nucleus is associated with impaired protein homeostasis and is a hallmark of several neurodegenerative diseases. Due to the absence of the autophagic machinery, nuclear protein aggregates require a solubilization step preceding degradation by the 26S proteasome. Using yeast, we identify a nuclear protein quality control pathway required for the clearance of protein aggregates. The nuclear J-domain protein Apj1 supports protein disaggregation together with Hsp70 but independent of the canonical disaggregase Hsp104. Disaggregation mediated by Apj1/Hsp70 promotes turnover rather than refolding. A loss of Apj1 activity uncouples disaggregation from proteasomal turnover, resulting in accumulation of toxic soluble protein species. Endogenous substrates of the Apj1/Hsp70 pathway include both nuclear and cytoplasmic proteins, which aggregate inside the nucleus upon proteotoxic stress. These findings demonstrate the coordinated activity of the Apj1/Hsp70 disaggregation system with the 26S proteasome in facilitating the clearance of toxic inclusions inside the nucleus., Graphical Abstract, Highlights • Nuclear Hsp40 Apj1 mediates proteolytic clearance of intra-nuclear protein inclusions • Apj1 supports Hsp104-independent disaggregation in vitro and in vivo • Apj1 competes with Hsp104 in disaggregation, supporting turnover instead of refolding • Inside the nucleus, Apj1 functions in quality control of nuclear and cytoplasmic proteins, den Brave et al. show that the Hsp40 chaperone Apj1 promotes Hsp70-dependent disaggregation of intra-nuclear protein aggregates. This Hsp104-independent disaggregation activity promotes proteolytic turnover and competes with substrate refolding. Co-ordinated disaggregation with turnover protects against potential toxicity of solubilized proteins.

Published

2020

6. Disassembly of Tau fibrils by the human Hsp70 disaggregation machinery generates small seeding-competent species

Author

Karine Madiona, Axel Mogk, Taxiarchis Katsinelos, Eliana Nachman, Bernd Bukau, Harm H. Kampinga, Luc Bousset, Anne S. Wentink, Kieren Allinson, Ronald Melki, William A. McEwan, Thomas R. Jahn, Carmen Nussbaum-Krammer, Center for Molecular Biology - Zentrum für Molekulare Biologie [Heidelberg, Germany] (ZMBH), Universität Heidelberg [Heidelberg], German Cancer Research Center - Deutsches Krebsforschungszentrum [Heidelberg] (DKFZ), Laboratoire des Maladies Neurodégénératives - UMR 9199 (LMN), Centre National de la Recherche Scientifique (CNRS)-Service MIRCEN (MIRCEN), Université Paris-Saclay-Institut de Biologie François JACOB (JACOB), Direction de Recherche Fondamentale (CEA) (DRF (CEA)), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Direction de Recherche Fondamentale (CEA) (DRF (CEA)), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay-Institut de Biologie François JACOB (JACOB), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA), Department of Clinical Neurosciences [Cambridge], University of Cambridge [UK] (CAM), Cambridge University Hospitals - NHS (CUH), University of Groningen [Groningen], Universität Heidelberg [Heidelberg] = Heidelberg University, Institut de Biologie François JACOB (JACOB), Service MIRCEN (MIRCEN), Université Paris-Saclay-Centre National de la Recherche Scientifique (CNRS)-Institut de Biologie François JACOB (JACOB), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay-Centre National de la Recherche Scientifique (CNRS)-Institut de Biologie François JACOB (JACOB), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Centre National de la Recherche Scientifique (CNRS), UK Dementia Research Institute (UK DRI), University College of London [London] (UCL), University Medical Center Groningen [Groningen] (UMCG), ANR-17-JPCD-0005,Protest-70,Protecting protein homeostasis in synucleinopathies and tauopathies by modulating the Hsp70/co-chaperone network(2017), European Project: (grant No 116060),IMPRiND, and Molecular Neuroscience and Ageing Research (MOLAR)

Subjects

0301 basic medicine, 70 kilodalton heat shock protein (Hsp70), [SDV]Life Sciences [q-bio], [SDV.NEU.NB]Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC]/Neurobiology, PROTEIN, Protein aggregation, Biochemistry, Nucleotide exchange factor, neurodegenerative disease, BINDING, PHOSPHORYLATION, biology, Chemistry, Brain, amyloid, Molecular Bases of Disease, ASSOCIATION, JBC Keywords: Tau protein (Tau), molecular chaperone, Cell biology, ALZHEIMERS-DISEASE, chaperone DNAJ (DNAJ), [SDV.NEU]Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC], Tauopathy, Amyloid, Tau protein, tau Proteins, protein aggregation, prion, 03 medical and health sciences, Alzheimer Disease, Heat shock protein, mental disorders, medicine, Humans, HSP70 Heat-Shock Proteins, [SDV.BBM]Life Sciences [q-bio]/Biochemistry, Molecular Biology, [SDV.BBM.BC]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Biochemistry [q-bio.BM], Molecular Biology, proteostasis, 030102 biochemistry & molecular biology, tauopathy, Cell Biology, 70-kilodalton heat shock protein (Hsp70), AGGREGATION, medicine.disease, GENE-EXPRESSION CHANGES, PATHOLOGY, 030104 developmental biology, Proteostasis, HEK293 Cells, Chaperone (protein), biology.protein, Tau, MEDIATE, HSP110

Abstract

International audience; The accumulation of amyloid Tau aggregates is implicated in Alzheimer’s disease (AD) and other tauopathies. Molecular chaperones are known to maintain protein homeostasis. Here, we show that an ATP-dependent human chaperone system disassembles Tau fibrils in vitro. We found that this function is mediated by the core chaperone HSC70, assisted by specific cochaperones, in particular class B J-domain proteins and a heat shock protein 110 (Hsp110)-type nucleotide exchange factor (NEF). The Hsp70 disaggregation machinery processed recombinant fibrils assembled from all six Tau isoforms as well as Sarkosyl-resistant Tau aggregates extracted from cell cultures and human AD brain tissues, demonstrating the ability of the Hsp70 machinery to recognize a broad range of Tau aggregates. However, the chaperone activity released monomeric and small oligomeric Tau species, which induced the aggregation of self-propagating Tau conformers in a Tau cell culture model. We conclude that the activity of the Hsp70 disaggregation machinery is a double-edged sword, as it eliminates Tau amyloids at the cost of generating new seeds.

Published

2020

7. Disassembly of Tau fibrils by the human Hsp70 disaggregation machinery generates small seeding-competent species

Author

Carmen Nussbaum-Krammer, Anne S. Wentink, Karine Madiona, William A. McEwan, Thomas R. Jahn, Harm H. Kampinga, Taxiarchis Katsinelos, Ronald Melki, Luc Bousset, Axel Mogk, Bernd Bukau, and Eliana Nachman

Subjects

0303 health sciences, Amyloid, biology, Chemistry, Fibril, In vitro, law.invention, Hsp70, Tau isoforms, Cell biology, 03 medical and health sciences, 0302 clinical medicine, Cell culture, law, Chaperone (protein), mental disorders, Recombinant DNA, biology.protein, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

The accumulation of amyloid Tau aggregates is implicated in Alzheimer’s disease and other Tauopathies. Molecular chaperones are known for their function in maintaining protein homeostasis by preventing the formation or promoting the disaggregation of amorphous and amyloid protein aggregates. Here we show that an ATP-dependent human chaperone system disassembles Tau fibrils in vitro. This function is mediated by the core chaperone Hsc70, assisted by specific co-chaperones, in particular class B J-domain proteins and an Hsp110-type NEF. Recombinant fibrils assembled from all six Tau isoforms as well as Sarkosyl-resistant Tau aggregates extracted from cell culture were processed by the Hsp70 disaggregation machinery, demonstrating the ability of this machinery to recognize a broad range of Tau aggregates. Chaperone treatment released monomeric, and small oligomeric Tau species, which induced the aggregation of self-propagating Tau species in a Tau cell culture model. We infer from these results that the activity of the Hsp70 disaggregation machinery is a double-sided sword as it attempts to eliminate Tau amyloids but with the price of generating new seeds. The Hsp70 disaggregase therefore has a crucial function in the Tau propagation cycle, rendering it a potential drug target in Tauopathies.

Published

2019

8. Nα-terminal acetylation of proteins by NatA and NatB serves distinct physiological roles in Saccharomyces cerevisiae

Author

Mostafa Zedan, Bernd Hessling, Günter Kramer, Joseph Barry, Ulrike Anne Friedrich, Kai Fenzl, Michael Knop, Ludovic C Gillet, and Bernd Bukau

Subjects

0301 basic medicine, 0303 health sciences, Nuclear gene, biology, 030302 biochemistry & molecular biology, Saccharomyces cerevisiae, Protein aggregation, Protein degradation, biology.organism_classification, General Biochemistry, Genetics and Molecular Biology, 3. Good health, Cell biology, Transcriptome, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Ribosomal protein, Acetylation, Chaperone (protein), biology.protein, Protein biosynthesis, Ribosome profiling, Gene, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

SummaryN-terminal (Nt)-acetylation is a highly prevalent co-translational protein modification in eukaryotes, catalyzed by at least five Nt-acetyltransferases (Nat) with differing specificities. Nt-acetylation has been implicated in protein quality control but its broad biological significance remains elusive. We investigated the roles of the two major Nats ofS. cerevisiae, NatA and NatB, by performing transcriptome, translatome and proteome profiling ofnatAΔ andnatBΔ mutants. Our results do not support a general role of Nt-acetylation in protein degradation but reveal an unexpected range of Nat-specific phenotypes. NatA is implicated in systemic adaptation control, asnatAΔ mutants display altered expression of transposons, sub-telomeric genes, pheromone response genes and nuclear genes encoding mitochondrial ribosomal proteins. NatB predominantly affects protein folding, asnatBΔ mutants accumulate protein aggregates, induce stress responses and display reduced fitness in absence of the ribosome-associated chaperone Ssb. These phenotypic differences indicate that controlling Nat activities may serve to elicit distinct cellular responses.

Published

2019

9. Protein Disaggregation in Multicellular Organisms

Author

Anne S. Wentink, Bernd Bukau, and Nadinath B. Nillegoda

Subjects

0301 basic medicine, biology, Protein Conformation, Chemistry, Protein aggregation, biology.organism_classification, Protein Aggregation, Pathological, Biochemistry, Hsp70, Cell biology, Protein Aggregates, 03 medical and health sciences, Multicellular organism, 030104 developmental biology, Proteostasis, Chaperone (protein), biology.protein, Animals, Humans, HSP70 Heat-Shock Proteins, Protein folding, Molecular Biology, Caenorhabditis elegans

Abstract

Protein aggregates are formed in cells with profoundly perturbed proteostasis, where the generation of misfolded proteins exceeds the cellular refolding and degradative capacity. They are a hallmark of protein conformational disorders and aged and/or environmentally stressed cells. Protein aggregation is a reversible process in vivo, which counteracts proteotoxicities derived from aggregate persistence, but the chaperone machineries involved in protein disaggregation in Metazoa were uncovered only recently. Here we highlight recent advances in the mechanistic understanding of the major protein disaggregation machinery mediated by the Hsp70 chaperone system and discuss emerging alternative disaggregation activities in multicellular organisms.

Published

2018

10. A prion-like domain in Hsp42 drives chaperone-facilitated aggregation of misfolded proteins

Author

Stephanie B.M. Miller, Axel Mogk, Sophia Ungelenk, Tomas Grousl, Bernd Bukau, Matthias P. Mayer, Chi-Ting Ho, and Maria Khokhrina

Subjects

0301 basic medicine, Saccharomyces cerevisiae Proteins, Prions, Saccharomyces cerevisiae, Protein aggregation, Article, 03 medical and health sciences, 0302 clinical medicine, Heat shock protein, Heat shock, Research Articles, Heat-Shock Proteins, biology, Cell Biology, Heat-Shock Proteins, Small, Cell biology, Cytosol, 030104 developmental biology, Chaperone (protein), biology.protein, Protein folding, Signal transduction, 030217 neurology & neurosurgery, Intracellular, Molecular Chaperones

Abstract

The facilitated aggregation of misfolded proteins is a proteostasis strategy important for cell function and viability, but the molecular mechanisms are poorly understood. Grousl et al. reveal how the intrinsically disordered domains of the small heat shock protein Hsp42 promote and control the aggregation of misfolded proteins during stress conditions in yeast., Chaperones with aggregase activity promote and organize the aggregation of misfolded proteins and their deposition at specific intracellular sites. This activity represents a novel cytoprotective strategy of protein quality control systems; however, little is known about its mechanism. In yeast, the small heat shock protein Hsp42 orchestrates the stress-induced sequestration of misfolded proteins into cytosolic aggregates (CytoQ). In this study, we show that Hsp42 harbors a prion-like domain (PrLD) and a canonical intrinsically disordered domain (IDD) that act coordinately to promote and control protein aggregation. Hsp42 PrLD is essential for CytoQ formation and is bifunctional, mediating self-association as well as binding to misfolded proteins. Hsp42 IDD confines chaperone and aggregase activity and affects CytoQ numbers and stability in vivo. Hsp42 PrLD and IDD are both crucial for cellular fitness during heat stress, demonstrating the need for sequestering misfolded proteins in a regulated manner.

Published

2018

11. Cellular Handling of Protein Aggregates by Disaggregation Machines

Author

Harm H. Kampinga, Bernd Bukau, and Axel Mogk

Subjects

0301 basic medicine, Protein Folding, SUBSTRATE-BINDING, Protein aggregation, DNAJ Protein, DAMAGED PROTEINS, Protein Aggregates, 03 medical and health sciences, Cytosol, 0302 clinical medicine, NEURODEGENERATIVE DISEASE, Heat shock protein, MOLECULAR CHAPERONE SSE1, DNAK CHAPERONE, HSP70 Heat-Shock Proteins, HSP110 Heat-Shock Proteins, Molecular Biology, Heat-Shock Proteins, Caenorhabditis elegans, Protein Unfolding, HSP70 CHAPERONES, biology, AAA PLUS DISAGGREGASE, Cell Biology, biology.organism_classification, Hsp70, Cell biology, 030104 developmental biology, Chaperone (protein), Proteolysis, biology.protein, Protein folding, CAENORHABDITIS-ELEGANS, 030217 neurology & neurosurgery, MISFOLDED PROTEINS, Molecular Chaperones, Protein Binding

Abstract

Both acute proteotoxic stresses that unfold proteins and expression of disease-causing mutant proteins that expose aggregation-prone regions can promote protein aggregation. Protein aggregates can interfere with cellular processes and deplete factors crucial for protein homeostasis. To cope with these challenges, cells are equipped with diverse folding and degradation activities to rescue or eliminate aggregated proteins. Here, we review the different chaperone disaggregation machines and their mechanisms of action. In all these machines, the coating of protein aggregates by Hsp70 chaperones represents the conserved, initializing step. In bacteria, fungi, and plants, Hsp70 recruits and activates Hsp100 disaggregases to extract aggregated proteins. In the cytosol of metazoa, Hsp70 is empowered by a specific cast of J-protein and Hsp110 co-chaperones allowing for standalone disaggregation activity. Both types of disaggregation machines are supported by small Hsps that sequester misfolded proteins.

Published

2018

12. The Hsp40 J‐domain modulates Hsp70 conformation and ATPase activity with a semi‐elliptical spring

Author

Neil Andrew D. Bascos, Bernd Bukau, Samuel J. Landry, and Matthias P. Mayer

Subjects

0301 basic medicine, Conformational change, Protein Conformation, ATPase, 010402 general chemistry, 01 natural sciences, Biochemistry, Potassium Chloride, 03 medical and health sciences, Protein Domains, ATP hydrolysis, Nuclear Magnetic Resonance, Biomolecular, Molecular Biology, Adenosine Triphosphatases, Regulation of gene expression, biology, Chemistry, Escherichia coli Proteins, Deuterium Exchange Measurement, Isothermal titration calorimetry, Articles, Nuclear magnetic resonance spectroscopy, HSP40 Heat-Shock Proteins, 0104 chemical sciences, 030104 developmental biology, Helix, Biophysics, biology.protein, Function (biology), Protein Binding

Abstract

Regulatory protein interactions are commonly attributed to lock‐and‐key associations that bring interacting domains together. However, studies in some systems suggest that regulation is not achieved by binding interactions alone. We report our investigations on specific physical characteristics required of the Hsp40 J‐domain to stimulate ATP hydrolysis in the Hsp40‐Hsp70 molecular chaperone machine. Biophysical analysis using isothermal titration calorimetry, and nuclear magnetic resonance spectroscopy reveals the importance of helix rigidity for the maintenance of Hsp40 function. Our results suggest that the functional J‐domain acts like a semi‐elliptical spring, wherein the resistance to bending upon binding to the Hsp70 ATPase modulates the ATPase domain conformational change and promotes ATP hydrolysis.

Published

2017

13. Role of sHsps in organizing cytosolic protein aggregation and disaggregation

Author

Bernd Bukau and Axel Mogk

Subjects

Models, Molecular, 0301 basic medicine, Protein Folding, Cell Biology, Biology, Protein aggregation, Biochemistry, Heat-Shock Proteins, Small, Cell biology, Protein Aggregates, 03 medical and health sciences, Cytosol, 030104 developmental biology, JUNQ and IPOD, Proteostasis, Chaperone (protein), Native state, biology.protein, Animals, Humans, Small Heat Shock Proteins, Protein folding, Protein quality

Abstract

Small heat shock proteins (sHsps) exhibit an ATP-independent chaperone activity to prevent the aggregation of misfolded proteins in vitro. The seemingly conflicting presence of sHsps in insoluble protein aggregates in cells obstructs a precise definition of sHsp function in proteostasis networks. Recent findings specify sHsp activities in protein quality control systems. The sHsps of yeast, Hsp42 and Hsp26, interact with early unfolding intermediates of substrates, keeping them in a ready-to-refold conformation close to the native state. This activity facilitates substrate refolding by ATP-dependent Hsp70-Hsp100 disaggregating chaperones. Hsp42 can actively sequester misfolded proteins and promote their deposition at specific cellular sites. This aggregase activity represents a cytoprotective protein quality control strategy. The aggregase function of Hsp42 controls the formation of cytosolic aggregates (CytoQs) under diverse stress regimes and can be reconstituted in vitro, demonstrating that Hsp42 is necessary and sufficient to promote protein aggregation. Substrates sequestered at CytoQs can be dissociated by Hsp70-Hsp100 disaggregases for subsequent triage between refolding and degradation pathways or are targeted for destruction by selective autophagy termed proteophagy.

Published

2017

14. Alternative modes of client binding enable functional plasticity of Hsp70

Author

Roman Kityk, Sander J. Tans, Sergey Bezrukavnikov, Alireza Mashaghi, Günter Kramer, Matthias P. Mayer, Anne S. Wentink, Bernd Bukau, David P. Minde, and Beate Zachmann-Brand

Subjects

0301 basic medicine, Protein Denaturation, Protein Folding, Conformational change, Optical Tweezers, Protein Conformation, Protein aggregation, Models, Biological, Protein Refolding, Substrate Specificity, Protein Aggregates, 03 medical and health sciences, Adenosine Triphosphate, Protein structure, ATP hydrolysis, HSP70 Heat-Shock Proteins, Multidisciplinary, biology, Protein Stability, Escherichia coli Proteins, GroEL, Single Molecule Imaging, 030104 developmental biology, Biochemistry, Chaperone (protein), biology.protein, Biophysics, Protein folding, Molecular tweezers, Protein Binding

Abstract

Hsp70 binds unfolded protein segments in its groove, but can also bind and stabilize folded protein structures, owing to its moveable lid, with ATP hydrolysis and co-chaperones allowing control of these contrasting effects. The protein-chaperone system centred on Hsp70 performs a variety of cellular control tasks, including folding assistance, protection against aggregation, trafficking and regulation of enzyme activity, a versatility that has been hard to reconcile with structural data, which suggest that Hsp70 only binds extended polypeptide segments. Now, using laser molecular tweezers, Sander Tans and colleagues show that the bacterial homolog of Hsp70, known as DnaK, relies on its 'groove' to bind unfolded proteins, but can also bind folded structures, thanks to its 'lid', with control of ATP hydrolysis by co-chaperones allowing regulation of such contrasting effects. Contrary to known stabilization mechanisms, through precise structural fit, Hsp70 can stabilize a vast repertoire of client proteins, through a clamp-like, ATP-driven conformational change. The Hsp70 system is a central hub of chaperone activity in all domains of life. Hsp70 performs a plethora of tasks, including folding assistance, protection against aggregation, protein trafficking, and enzyme activity regulation1,2,3,4,5, and interacts with non-folded chains, as well as near-native, misfolded, and aggregated proteins6,7,8,9,10. Hsp70 is thought to achieve its many physiological roles by binding peptide segments that extend from these different protein conformers within a groove that can be covered by an ATP-driven helical lid11,12,13,14,15. However, it has been difficult to test directly how Hsp70 interacts with protein substrates in different stages of folding and how it affects their structure. Moreover, recent indications of diverse lid conformations in Hsp70–substrate complexes raise the possibility of additional interaction mechanisms15,16,17,18. Addressing these issues is technically challenging, given the conformational dynamics of both chaperone and client, the transient nature of their interaction, and the involvement of co-chaperones and the ATP hydrolysis cycle19. Here, using optical tweezers, we show that the bacterial Hsp70 homologue (DnaK) binds and stabilizes not only extended peptide segments, but also partially folded and near-native protein structures. The Hsp70 lid and groove act synergistically when stabilizing folded structures: stabilization is abolished when the lid is truncated and less efficient when the groove is mutated. The diversity of binding modes has important consequences: Hsp70 can both stabilize and destabilize folded structures, in a nucleotide-regulated manner; like Hsp90 and GroEL, Hsp70 can affect the late stages of protein folding; and Hsp70 can suppress aggregation by protecting partially folded structures as well as unfolded protein chains. Overall, these findings in the DnaK system indicate an extension of the Hsp70 canonical model that potentially affects a wide range of physiological roles of the Hsp70 system.

Published

2016

15. Bacterial and Yeast AAA + Disaggregases ClpB and Hsp104 Operate through Conserved Mechanism Involving Cooperation with Hsp70

Author

Bernd Bukau, Kamila B. Franke, Axel Mogk, Anna Szlachcic, Eva Kummer, and Sophia Ungelenk

Subjects

0301 basic medicine, Saccharomyces cerevisiae Proteins, Protein subunit, Saccharomyces cerevisiae, Protein Aggregates, 03 medical and health sciences, Structural Biology, Heat shock protein, Protein Interaction Mapping, Escherichia coli, HSP70 Heat-Shock Proteins, Molecular Biology, Heat-Shock Proteins, Derepression, biology, Escherichia coli Proteins, Endopeptidase Clp, biology.organism_classification, Cell biology, 030104 developmental biology, Proteostasis, Biochemistry, Chaperone (protein), biology.protein, Protein folding, CLPB

Abstract

Escherichia coli ClpB and Saccharomyces cerevisiae Hsp104 are members of the Hsp100 family of ring-forming hexameric AAA+ chaperones that promote the solubilization of aggregated proteins and the propagation of prions. ClpB and Hsp104 cooperate with cognate Hsp70 chaperones for substrate targeting and activation of ATPase and substrate threading, achieved by transient Hsp70 binding to the repressing ClpB/Hsp104 M-domain. Fundamental differences in ATPase regulation and disaggregation mechanisms have been reported; however, these differences are raising doubts regarding the working principle of this AAA+ chaperone. In particular, unique functional plasticity was suggested to specifically enable Hsp104 to circumvent Hsp70 requirement for derepression in protein disaggregation and prion propagation. We show here that both ClpB and Hsp104 cooperation with Hsp70 is crucial for efficient protein disaggregation and, in contrast to earlier claims, cannot be circumvented by activating M-domain mutations. Activation of ClpB and Hsp104 requires two signals, relief of M-domain repression and substrate binding, leading to increased ATPase subunit coupling. These data demonstrate that ClpB and Hsp104 operate by the same basic mechanism, underscore a dominant function of Hsp70 in regulating ClpB/Hsp104 activity, and explain a plethora of in vivo studies showing a crucial function of Hsp70 in proteostasis and prion propagation.

Published

2016

16. The C-terminal tail of the bacterial translocation ATPase SecA modulates its activity

Author

Mohammed Jamshad, Bernd Bukau, Gareth W. Hughes, Günter Kramer, Fiyaz Mohammed, Kazi Fahmida Rahman, Damon Huber, Max Wynne, Douglas G. Ward, Scott A. White, and Timothy J. Knowles

Subjects

Models, Molecular, SecA, 0301 basic medicine, Protein Folding, Structural Biology and Molecular Biophysics, ATPase, environment and public health, Ribosome, Substrate Specificity, Biology (General), Phylogeny, Adenosine Triphosphatases, protein translocation, biology, Chemistry, Escherichia coli Proteins, General Neuroscience, SAXS, General Medicine, Transport protein, Cross-Linking Reagents, ribosome, Medicine, Protein Binding, Research Article, QH301-705.5, Science, 030106 microbiology, General Biochemistry, Genetics and Molecular Biology, Evolution, Molecular, 03 medical and health sciences, Protein Domains, Biochemistry and Chemical Biology, Ribosomal protein, protein secretion, Escherichia coli, Amino Acid Sequence, SecA Proteins, General Immunology and Microbiology, E. coli, 030104 developmental biology, Secretory protein, Structural biology, metal-binding domain, Cytoplasm, Bacterial Translocation, Biocatalysis, biology.protein, Biophysics, bacteria, Mutant Proteins, Peptides, Ribosomes, Linker

Abstract

In bacteria, the translocation of proteins across the cytoplasmic membrane by the Sec machinery requires the ATPase SecA. SecA binds ribosomes and recognises nascent substrate proteins, but the molecular mechanism of nascent substrate recognition is unknown. We investigated the role of the C-terminal tail (CTT) of SecA in nascent polypeptide recognition. The CTT consists of a flexible linker (FLD) and a small metal-binding domain (MBD). Phylogenetic analysis and ribosome binding experiments indicated that the MBD interacts with 70S ribosomes. Disruption of the MBD only or the entire CTT had opposing effects on ribosome binding, substrate-protein binding, ATPase activity and in vivo function, suggesting that the CTT influences the conformation of SecA. Site-specific crosslinking indicated that F399 in SecA contacts ribosomal protein uL29, and binding to nascent chains disrupts this interaction. Structural studies provided insight into the CTT-mediated conformational changes in SecA. Our results suggest a mechanism for nascent substrate protein recognition.

Published

2019

17. Author response: The C-terminal tail of the bacterial translocation ATPase SecA modulates its activity

Author

Günter Kramer, Max Wynne, Gareth W. Hughes, Kazi Fahmida Rahman, Mohammed Jamshad, Damon Huber, Bernd Bukau, Fiyaz Mohammed, Douglas G. Ward, Scott A. White, and Timothy J. Knowles

Subjects

Terminal (electronics), biology, Chemistry, ATPase, biology.protein, Bacterial translocation, Cell biology

Published

2019

18. Trigger Factor Reduces the Force Exerted on the Nascent Chain by a Cotranslationally Folding Protein

Author

Gunnar von Heijne, Annika Müller-Lucks, Günter Kramer, Bernd Bukau, and Ola B. Nilsson

Subjects

0301 basic medicine, Peptidylprolyl isomerase, Protein Folding, biology, Escherichia coli Proteins, Peptidylprolyl Isomerase, GroEL, Ribosome, Molecular biology, Tetrahydrofolate Dehydrogenase, 03 medical and health sciences, 030104 developmental biology, Structural Biology, Protein Biosynthesis, Chaperone (protein), Codon usage bias, Dihydrofolate reductase, Protein biosynthesis, biology.protein, Biophysics, Protein folding, Molecular Biology, Heat-Shock Proteins, Molecular Chaperones

Abstract

Cotranslational protein folding can generate pulling forces on the nascent chain that can affect the instantaneous translation rate and thereby possibly feed back on the folding process. Such feedback would represent a new way of coupling translation and folding, different from coupling based on, for example, codon usage. However, to date, we have carried out the experiments used to measure pulling forces generated by cotranslational protein folding either in reconstituted in vitro translation systems lacking chaperones, in ill-defined cell lysates, or in vivo; hence, the effects of chaperones on force generation by folding are unknown. Here, we have studied the cotranslational folding of dihydrofolate reductase (DHFR) in the absence and in the presence of the chaperones trigger factor (TF) and GroEL/ES. DHFR was tethered to the ribosome via a C-terminal linker of varying length, ending with the SecM translational arrest peptide that serves as an intrinsic force sensor reporting on the force generated on the nascent chain when DHFR folds. We find that DHFR folds into its native structure only when it has emerged fully outside the ribosome and that TF and GroEL alone substantially reduces the force generated on the nascent chain by the folding of DHFR, while GroEL/ES has no effect. TF therefore weakens the possible coupling between cotranslational folding and translation.

Published

2016

19. The C-terminal tail of the bacterial translocation ATPase SecA modulates its activity

Author

Kazi Fahmida Rahman, Scott A. White, Timothy J. Knowles, Guenter Kramer, Damon Huber, Mohammed Jamshad, Douglas G. Ward, Gareth W. Hughes, Bernd Bukau, and Fiyaz Mohammed

Subjects

biology, Chemistry, ATPase, Substrate (chemistry), Chromosomal translocation, biology.organism_classification, Ribosome, environment and public health, Cytoplasm, Biophysics, biology.protein, bacteria, Linker, Function (biology), Bacteria

Abstract

SecA is an evolutionarily conserved and essential ATPase that is required for the translocation of a subset of proteins across the cytoplasmic membrane in bacteria. SecA can recognise proteins that are destined for translocation as they are still being synthesised in order to deliver them to the membrane-bound Sec machinery. However, the mechanism of cotranslational substrate recognition is not well defined. In E. coli, SecA contains a relatively long C-terminal tail (CTT), which consists of a small metal-binding domain (MBD) that is attached to the C-terminus of the catalytic core by a flexible linker (FLD). In this study, we investigated the role of the CTT in the interaction of SecA with the ribosome and nascent polypeptides. Previous work indicates that the CTT is required for interaction with the molecular chaperone SecB. However, phylogenetic analysis suggested that the CTT (and the MBD in particular) has an additional function. Binding experiments indicated that the CTT interacts with 70S ribosomes, and disruption of the entire CTT moderately reduced the affinity of SecA for ribosomes. However, disruption of the MBD alone significantly increased the affinity of SecA for ribosomes and inhibited the interaction of SecA with substrate protein, suggesting that the FLD affects the conformation of SecA. Photocrosslinking and mass spectrometry indicated that the FLD is bound at the site where SecA binds to substrate proteins. Structural analysis by x-ray crystallography and small-angle x-ray scattering (SAXS) provided insight into how the CTT influences the structure of SecA in solution. Finally, site-specific crosslinking experiments indicated that binding to nascent substrate protein affects the conformation of SecA. Taken together, our results suggest that the CTT regulates the ability of SecA to interact with substrate proteins.

Published

2018

20. Stand-alone ClpG disaggregase confers superior heat tolerance to bacteria

Author

Lothar Jänsch, Shady Mansour Kamal, Hyunhee Kim, Kamila B. Franke, Jasmin Jäger, Manfred Nimtz, Ute Römling, Bernd Bukau, Heinrich Lünsdorf, Janja Trček, Changhan Lee, and Axel Mogk

Subjects

0301 basic medicine, Hot Temperature, Gene Transfer, Horizontal, ATPase, 030106 microbiology, Protein aggregation, medicine.disease_cause, Gene Expression Regulation, Enzymologic, Virulence factor, 03 medical and health sciences, Bacterial Proteins, medicine, Escherichia coli, Phylogeny, Multidisciplinary, biology, Chemistry, Pseudomonas aeruginosa, Gene Expression Regulation, Bacterial, biology.organism_classification, Adaptation, Physiological, Cell biology, PNAS Plus, Horizontal gene transfer, biology.protein, Bacteria, Binding domain

Abstract

AAA+ disaggregases solubilize aggregated proteins and confer heat tolerance to cells. Their disaggregation activities crucially depend on partner proteins, which target the AAA+ disaggregases to protein aggregates while concurrently stimulating their ATPase activities. Here, we report on two potent ClpG disaggregase homologs acquired through horizontal gene transfer by the species Pseudomonas aeruginosa and subsequently abundant P. aeruginosa clone C. ClpG exhibits high, stand-alone disaggregation potential without involving any partner cooperation. Specific molecular features, including high basal ATPase activity, a unique aggregate binding domain, and almost exclusive expression in stationary phase distinguish ClpG from other AAA+ disaggregases. Consequently, ClpG largely contributes to heat tolerance of P. aeruginosa primarily in stationary phase and boosts heat resistance 100-fold when expressed in Escherichia coli This qualifies ClpG as a potential persistence and virulence factor in P. aeruginosa.

Published

2017

21. Cotranslational assembly of protein complexes in eukaryotes revealed by ribosome profiling

Author

Günter Kramer, Kevin Klann, Bernd Bukau, Frank Tippmann, Kristina Döring, Ulrike A. Friedrich, Ayala Shiber, Mostafa Zedan, and Dorina Merker

Subjects

0301 basic medicine, Models, Molecular, Saccharomyces cerevisiae Proteins, Protein subunit, Saccharomyces cerevisiae, Plasma protein binding, Article, Amino Acyl-tRNA Synthetases, 03 medical and health sciences, 0302 clinical medicine, Protein biosynthesis, HSP70 Heat-Shock Proteins, Ribosome profiling, RNA, Messenger, Multidisciplinary, biology, Chemistry, Ribosomal RNA, biology.organism_classification, Cell biology, Protein Subunits, 030104 developmental biology, Chaperone (protein), Multiprotein Complexes, Protein Biosynthesis, Proteome, biology.protein, Fatty Acid Synthases, Ribosomes, 030217 neurology & neurosurgery, Protein Binding

Abstract

The folding of newly synthesized proteins to the native state is a major challenge within the crowded cellular environment, as non-productive interactions can lead to misfolding, aggregation and degradation1. Cells cope with this challenge by coupling synthesis with polypeptide folding and by using molecular chaperones to safeguard folding cotranslationally2. However, although most of the cellular proteome forms oligomeric assemblies3, little is known about the final step of folding: the assembly of polypeptides into complexes. In prokaryotes, a proof-of-concept study showed that the assembly of heterodimeric luciferase is an organized cotranslational process that is facilitated by spatially confined translation of the subunits encoded on a polycistronic mRNA4. In eukaryotes, however, fundamental differences—such as the rarity of polycistronic mRNAs and different chaperone constellations—raise the question of whether assembly is also coordinated with translation. Here we provide a systematic and mechanistic analysis of the assembly of protein complexes in eukaryotes using ribosome profiling. We determined the in vivo interactions of the nascent subunits from twelve hetero-oligomeric protein complexes of Saccharomyces cerevisiae at near-residue resolution. We find nine complexes assemble cotranslationally; the three complexes that do not show cotranslational interactions are regulated by dedicated assembly chaperones5–7. Cotranslational assembly often occurs uni-directionally, with one fully synthesized subunit engaging its nascent partner subunit, thereby counteracting its propensity for aggregation. The onset of cotranslational subunit association coincides directly with the full exposure of the nascent interaction domain at the ribosomal tunnel exit. The action of the ribosome-associated Hsp70 chaperone Ssb8 is coordinated with assembly. Ssb transiently engages partially synthesized interaction domains and then dissociates before the onset of partner subunit association, presumably to prevent premature assembly interactions. Our study shows that cotranslational subunit association is a prevalent mechanism for the assembly of hetero-oligomers in yeast and indicates that translation, folding and the assembly of protein complexes are integrated processes in eukaryotes. Cotranslational assembly is a prevalent mechanism for the formation of oligomeric complexes in Saccharomyces cerevisiae, with one subunit serving as scaffold for the translation of partner subunits.

Published

2017

22. Regulatory coiled-coil domains promote head-to-head assemblies of AAA+ chaperones essential for tunable activity control

Author

Marta Carroni, Bernd Bukau, Sebastian Gremer, Axel Mogk, Kürşad Turgay, Jasmin Jäger, Ingo Hantke, Felix Gloge, Kamila B. Franke, Michael Maurer, and Daniela Linder

Subjects

0301 basic medicine, Dewey Decimal Classification::500 | Naturwissenschaften::570 | Biowissenschaften, Biologie, Protein Conformation, medicine.medical_treatment, polymerase chain reaction, Mutant, cryoelectron microscopy, heat shock protein, AAA+ protein, light scattering, Western blotting, stress, chaperone, Biology (General), Heat-Shock Proteins, Coiled coil, biology, Chemistry, General Neuroscience, Signal transducing adaptor protein, size exclusion chromatography, General Medicine, Cell biology, Biochemistry, protein degradation, Medicine, cytotoxicity, Protein folding, Research Article, Proteases, cross linking, Staphylococcus aureus, QH301-705.5, Head to head, Science, Virulence, anisotropy, Protein degradation, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Bacterial Proteins, Biochemistry and Chemical Biology, Heat shock protein, ddc:570, medicine, Penicillin-Binding Proteins, ATPase activity assay, enzyme specificity, Psychological repression, cell viability, Protease, nonhuman, 030102 biochemistry & molecular biology, General Immunology and Microbiology, Cryoelectron Microscopy, E. coli, image processing, 030104 developmental biology, Chaperone (protein), biology.protein, Threading (protein sequence), Protein Multimerization, polyacrylamide gel electrophoresis, Molecular Chaperones

Abstract

Ring-forming AAA+ chaperones exert ATP-fueled substrate unfolding by threading through a central pore. This activity is potentially harmful requiring mechanisms for tight repression and substrate-specific activation. The AAA+ chaperone ClpC with the peptidase ClpP forms a bacterial protease essential to virulence and stress resistance. The adaptor MecA activates ClpC by targeting substrates and stimulating ClpC ATPase activity. We show how ClpC is repressed in its ground state by determining ClpC cryo-EM structures with and without MecA. ClpC forms large two-helical assemblies that associate via head-to-head contacts between coiled-coil middle domains (MDs). MecA converts this resting state to an active planar ring structure by binding to MD interaction sites. Loss of ClpC repression in MD mutants causes constitutive activation and severe cellular toxicity. These findings unravel an unexpected regulatory concept executed by coiled-coil MDs to tightly control AAA+ chaperone activity., eLife digest If a protein does not fold into the correct shape, it may be unable to act correctly and can harm cells. As a result, cells contain biological machines that refold or break down misfolded proteins. ATP-dependent AAA+ proteases are an example of such machines. Their activity needs to be tightly controlled because breaking down the wrong proteins can also harm cells. ATP-dependent AAA+ proteases form ring-shaped assemblies that are composed of AAA+ proteins and an associated peptidase. In bacteria, the AAA+ protein called ClpC can be crucial for resisting stress and infecting host cells. Adapter proteins help to activate ClpC by binding to extra domains that are fused to or inserted into the protein. This method of activation also requires repressing elements that ensure that the activity of ClpC remains low when the adapter proteins are not present. It was not known how this repression works. Carroni, Franke et al. have now used a technique called cryo-electron microscopy to study the structures of repressed and adapter-activated ClpC from pathogenic bacteria called Staphylococcus aureus. In the repressed state, 10 molecules of ClpC interact to form two assemblies that interact via regions called middle domains. The middle domains have a “coiled coil” structure, and they interact via their ends in a head-to-head manner. In the repressed state ClpC cannot interact with its partner peptidase and the shape of the assembly shields the sites where adapter proteins can bind. This renders ClpC inactive. Carroni, Franke et al. also studied ClpC proteins that had mutations to the middle domain that prevented the repressed state from forming. The mutant proteins remain in a constantly active state that is highly toxic to bacteria. Bacteria are increasingly evolving to resist the effects of the antibiotics commonly used to treat infections. This is a severe problem, and we need to develop new antibiotic drugs that will kill these bacteria. AAA+ proteases have been identified as possible targets for new antibacterial drugs. The results presented by Carroni, Franke et al. suggest that disrupting the repressing activity of ClpC middle domains could be an effective way for such drugs to work.

Published

2017

23. Human Hsp70 Disaggregase Reverses Parkinson’s-Linked α-Synuclein Amyloid Fibrils

Author

D. Lys Guilbride, Marta Carroni, Helen R. Saibil, Bernd Bukau, Axel Mogk, Xuechao Gao, Nadinath B. Nillegoda, Matthias P. Mayer, Anna Szlachcic, and Carmen Nussbaum-Krammer

Subjects

Amyloid, Electron Microscope Tomography, macromolecular substances, In Vitro Techniques, Protein aggregation, bcs, Fibril, Protein Aggregation, Pathological, Article, Nucleotide exchange factor, Protein Aggregates, chemistry.chemical_compound, mental disorders, Humans, HSP70 Heat-Shock Proteins, HSP110 Heat-Shock Proteins, Molecular Biology, Alpha-synuclein, biology, HSC70 Heat-Shock Proteins, P3 peptide, Parkinson Disease, Cell Biology, HSP40 Heat-Shock Proteins, Cell biology, Kinetics, Solubility, chemistry, Biochemistry, Chaperone (protein), alpha-Synuclein, biology.protein, Protein Multimerization, Intracellular, Molecular Chaperones

Abstract

Intracellular amyloid fibrils linked to neurodegenerative disease typically accumulate in an age-related manner, suggesting inherent cellular capacity for counteracting amyloid formation in early life. Metazoan molecular chaperones assist native folding and block polymerization of amyloidogenic proteins, preempting amyloid fibril formation. Chaperone capacity for amyloid disassembly, however, is unclear. Here, we show that a specific combination of human Hsp70 disaggregase-associated chaperone components efficiently disassembles α-synuclein amyloid fibrils characteristic of Parkinson’s disease in vitro. Specifically, the Hsc70 chaperone, the class B J-protein DNAJB1, and an Hsp110 family nucleotide exchange factor (NEF) provide ATP-dependent activity that disassembles amyloids within minutes via combined fibril fragmentation and depolymerization. This ultimately generates non-toxic α-synuclein monomers. Concerted, rapid interaction cycles of all three chaperone components with fibrils generate the power stroke required for disassembly. This identifies a powerful human Hsp70 disaggregase activity that efficiently disassembles amyloid fibrils and points to crucial yet undefined biology underlying amyloid-based diseases.

Published

2015

24. Spatially Organized Aggregation of Misfolded Proteins as Cellular Stress Defense Strategy

Author

Bernd Bukau, Stephanie B.M. Miller, and Axel Mogk

Subjects

Protein Folding, Saccharomyces cerevisiae Proteins, Amino Acid Transport Systems, Signal transducing adaptor protein, Aggrephagy, Saccharomyces cerevisiae, Protein aggregation, Biology, Cell biology, Protein Aggregates, Aggresome, JUNQ and IPOD, Proteasome, Stress, Physiological, Structural Biology, Heat shock protein, Chaperone (protein), biology.protein, Animals, Humans, Molecular Biology, Heat-Shock Proteins

Abstract

An evolutionary conserved response of cells to proteotoxic stress is the organized sequestration of misfolded proteins into subcellular deposition sites. In Saccharomyces cerevisiae, three major sequestration sites for misfolded proteins exist, IPOD (insoluble protein deposit), INQ (intranuclear quality control compartment) [former JUNQ (juxtanuclear quality control compartment)] and CytoQ. IPOD is perivacuolar and predominantly sequesters amyloidogenic proteins. INQ and CytoQs are stress-induced deposits for misfolded proteins residing in the nucleus and the cytosol, respectively, and requiring cell-compartment-specific aggregases, nuclear Btn2 and cytosolic Hsp42 for formation. The organized aggregation of misfolded proteins is proposed to serve several purposes collectively increasing cellular fitness and survival under proteotoxic stress. These include (i) shielding of cellular processes from interference by toxic protein conformers, (ii) reducing the substrate burden for protein quality control systems upon immediate stress, (iii) orchestrating chaperone and protease functions for efficient repair or degradation of damaged proteins [this involves initial extraction of aggregated molecules via the Hsp70/Hsp104 bi-chaperone system followed by either refolding or proteasomal degradation or removal of entire aggregates by selective autophagy (aggrephagy) involving the adaptor protein Cue5] and (iv) enabling asymmetric retention of protein aggregates during cell division, thereby allowing for damage clearance in daughter cells. Regulated protein aggregation thus serves cytoprotective functions vital for the maintenance of cell integrity and survival even under adverse stress conditions and during aging.

Published

2015

25. Operon structure and cotranslational subunit association direct protein assembly in bacteria

Author

Günter Kramer, Peer Bork, Pablo Minguez, Bernd Bukau, D. Lys Guilbride, Josef J. Auburger, and Yu-Wei Shieh

Subjects

Operon, Recombinant Fusion Proteins, Protein subunit, Green Fluorescent Proteins, Ribosome, Protein Structure, Secondary, Protein structure, Bacterial Proteins, Gene Order, Escherichia coli, Protein biosynthesis, RNA, Messenger, Vibrio, Genetics, Multidisciplinary, Bacteria, biology, RNA, Cell biology, Luciferases, Bacterial, Luminescent Proteins, Protein Subunits, Cytosol, Genes, Bacterial, Protein Biosynthesis, Chaperone (protein), biology.protein, Ribosomes, Molecular Chaperones

Abstract

Proximity best for building protein complexes The synthesis of protein subunits and their assembly into a fully functional complex are generally thought to be two distinct processes. Shieh et al. studied the synthesis and assembly of the luciferase complex in Escherichia coli. Organization of the luciferase subunits LuxA and LuxB side by side into an operon promotes their colocalized synthesis and assembly into an active enzyme complex. Indeed, the association between the subunits occurs as they are being synthesized on ribosomes, which helps order the sequence of subunit interactions. Science , this issue p. 678

Published

2015

26. The growing world of small heat shock proteins: from structure to functions

Author

Angelo Poletti, Elizabeth Vierling, Martin Haslbeck, Lawrence E. Hightower, Melinda Tóth, Johannes Buchner, Wilbert C. Boelens, Robert M. Tanguay, Cecilia Emanuelsson, Krzysztof Liberek, John A. Carver, Stéphanie Finet, Ivor J. Benjamin, Pierre Goloubinoff, Sergei V. Strelkov, Bernd Bukau, Patrick A. Arrigo, Serena Carra, Justin L. P. Benesch, Nikola Golenhofen, Roy A. Quinlan, Kathryn A. McMenimen, Britta Bartelt-Kirbach, Harm H. Kampinga, Heath Ecroyd, Bianca J. J. M. Brundel, Nikolai B. Gusev, Hassane S. Mchaourab, Simon Alberti, and Rachel E. Klevit

Subjects

0301 basic medicine, Protein aggregates, Heart Diseases, CHAPERONE-LIKE ACTIVITY, Protein Conformation, Cellular differentiation, ALPHA-B-CRYSTALLIN, MYOGENIC DIFFERENTIATION, Protein aggregation, Small heat shock proteins, MIMICKING PHOSPHORYLATION, Biochemistry, 03 medical and health sciences, SYNUCLEIN AGGREGATION, Protein Aggregates, Protein structure, DESMIN-RELATED MYOPATHY, Hsp27, Muscular Diseases, Animals, Humans, Small Heat Shock Proteins, Protein Interaction Maps, N-TERMINAL DOMAIN, 030102 biochemistry & molecular biology, biology, MOTOR NEUROPATHY, Bio-Molecular Chemistry, Neurodegenerative Diseases, IN-VITRO, Cell Biology, Cell cycle, QUATERNARY ORGANIZATION, Hsp70, Cell biology, Heat-Shock Proteins, Small, 030104 developmental biology, Protein conformation, Proteome, biology.protein, Neurological diseases, Protein homeostasis, Function (biology)

Abstract

Small heat shock proteins (sHSPs) are present in all kingdoms of life and play fundamental roles in cell biology. sHSPs are key components of the cellular protein quality control system, acting as the first line of defense against conditions that affect protein homeostasis and proteome stability, from bacteria to plants to humans. sHSPs have the ability to bind to a large subset of substrates and to maintain them in a state competent for refolding or clearance with the assistance of the HSP70 machinery. sHSPs participate in a number of biological processes, from the cell cycle, to cell differentiation, from adaptation to stressful conditions, to apoptosis, and, even, to the transformation of a cell into a malignant state. As a consequence, sHSP malfunction has been implicated in abnormal placental development and preterm deliveries, in the prognosis of several types of cancer, and in the development of neurological diseases. Moreover, mutations in the genes encoding several mammalian sHSPs result in neurological, muscular, or cardiac age-related diseases in humans. Loss of protein homeostasis due to protein aggregation is typical of many age-related neurodegenerative and neuromuscular diseases. In light of the role of sHSPs in the clearance of un/misfolded aggregation-prone substrates, pharmacological modulation of sHSP expression or function and rescue of defective sHSPs represent possible routes to alleviate or cure protein conformation diseases. Here, we report the latest news and views on sHSPs discussed by many of the world’s experts in the sHSP field during a dedicated workshop organized in Italy (Bertinoro, CEUB, October 12–15, 2016).

Published

2017

27. In vivo properties of the disaggregase function of J-proteins and Hsc70 in Caenorhabditis elegans stress and aging

Author

Bernd Bukau, Richard I. Morimoto, Kristin Arnsburg, Anna Szlachcic, Annika Scior, D. Lys Guilbride, Nadinath B. Nillegoda, and Janine Kirstein

Subjects

0301 basic medicine, Aging, Protein aggregation, stress recovery, Nucleotide exchange factor, Protein Aggregates, 03 medical and health sciences, 0302 clinical medicine, longevity, Stress, Physiological, RNA interference, Animals, Humans, metazoan, HSP70 Heat-Shock Proteins, protein disaggregation, Caenorhabditis elegans, Heat-Shock Proteins, Genetics, Gene knockdown, Hsp40, biology, C. elegans, J-protein, network, Original Articles, Cell Biology, J‐protein, biology.organism_classification, Cell biology, Hsp70, 030104 developmental biology, Chaperone (protein), biology.protein, Original Article, Protein quality, 030217 neurology & neurosurgery

Abstract

Summary Protein aggregation is enhanced upon exposure to various stress conditions and aging, which suggests that the quality control machinery regulating protein homeostasis could exhibit varied capacities in different stages of organismal lifespan. Recently, an efficient metazoan disaggregase activity was identified in vitro, which requires the Hsp70 chaperone and Hsp110 nucleotide exchange factor, together with single or cooperating J-protein co-chaperones of classes A and B. Here, we describe how the orthologous Hsp70s and J-protein of Caenorhabditis elegans work together to resolve protein aggregates both in vivo and in vitro to benefit organismal health. Using an RNAi knockdown approach, we show that class A and B J-proteins cooperate to form an interactive flexible network that relocalizes to protein aggregates upon heat shock and preferentially recruits constitutive Hsc70 to disaggregate heat-induced protein aggregates and polyQ aggregates that form in an age-dependent manner. Cooperation between class A and B J-proteins is also required for organismal health and promotes thermotolerance, maintenance of fecundity, and extended viability after heat stress. This disaggregase function of J-proteins and Hsc70 therefore constitutes a powerful regulatory network that is key to Hsc70-based protein quality control mechanisms in metazoa with a central role in the clearance of aggregates, stress recovery, and organismal fitness in aging.

Published

2017

28. Evolution of an intricate J-protein network driving protein disaggregation in eukaryotes

Author

Rebecca C. Wade, Niels Alberts, Bernd Bukau, Antonia Stank, Alessandro Barducci, Nadinath B. Nillegoda, Duccio Malinverni, Paolo De Los Rios, Anna Szlachcic, Centre de Biochimie Structurale [Montpellier] (CBS), and Centre National de la Recherche Scientifique (CNRS)-Université de Montpellier (UM)-Institut National de la Santé et de la Recherche Médicale (INSERM)

Subjects

0301 basic medicine, Models, Molecular, Protein Folding, Protein Conformation, S. cerevisiae, Protein aggregation, Biochemistry, Conserved sequence, Hsp70, chaperone, Biology (General), Heat-Shock Proteins, Phylogeny, Genetics, biology, General Neuroscience, Escherichia coli Proteins, General Medicine, Biophysics and Structural Biology, Medicine, Protein folding, Fundamental change, Protein network, Research Article, QH301-705.5, Science, Computational biology, Saccharomyces cerevisiae, General Biochemistry, Genetics and Molecular Biology, Functional networks, Evolution, Molecular, 03 medical and health sciences, Protein Aggregates, evolution, Escherichia coli, protein disaggregation and refolding, Humans, [SDV.BBM]Life Sciences [q-bio]/Biochemistry, Molecular Biology, Hsp40, General Immunology and Microbiology, E. coli, 030104 developmental biology, J-protein, Structural biology, Chaperone (protein), biology.protein, HeLa Cells, Molecular Chaperones

Abstract

Hsp70 participates in a broad spectrum of protein folding processes extending from nascent chain folding to protein disaggregation. This versatility in function is achieved through a diverse family of J-protein cochaperones that select substrates for Hsp70. Substrate selection is further tuned by transient complexation between different classes of J-proteins, which expands the range of protein aggregates targeted by metazoan Hsp70 for disaggregation. We assessed the prevalence and evolutionary conservation of J-protein complexation and cooperation in disaggregation. We find the emergence of a eukaryote-specific signature for interclass complexation of canonical J-proteins. Consistently, complexes exist in yeast and human cells, but not in bacteria, and correlate with cooperative action in disaggregation in vitro. Signature alterations exclude some J-proteins from networking, which ensures correct J-protein pairing, functional network integrity and J-protein specialization. This fundamental change in J-protein biology during the prokaryote-to-eukaryote transition allows for increased fine-tuning and broadening of Hsp70 function in eukaryotes. DOI: http://dx.doi.org/10.7554/eLife.24560.001, eLife digest All cells must maintain their proteins in a correctly folded shape to survive. The task of sustaining a healthy set of proteins has increased with the rise of complex life from prokaryotes (such as bacteria) that form simple single-celled organisms to eukaryotes (such as yeast, plants and multicellular animals). As a result of organisms ageing or acquiring genetic mutations, or under stressful conditions such as high temperature, proteins can lose their normal shape and clump together to form “aggregates”. These aggregates are potentially toxic to cells and have been linked to many human diseases including neurodegeneration and cancer. Cells contain molecular machines that help break down aggregates and subsequently recycle or rescue trapped proteins. Some of these machines are based around a protein called Hsp70, which can perform a wide range of protein folding processes. So-called J-proteins help Hsp70 to select aggregates to be targeted for break down. It used to be thought that different classes of J-proteins interacted with Hsp70 separately. However, in 2015, researchers showed that in humans, two different classes of J-proteins can bind to each other to form a “complex”, which has distinct aggregate selection properties. Now, Nillegoda et al. – including several of the researchers involved in the 2015 study – have examined the evolutionary history of these J-protein complexes. This revealed that different classes (A and B) of J-proteins first cooperated after prokaryotes and eukaryotes diverged from each other. In particular, the molecular machinery that breaks down aggregates in yeast cells – but not the machinery found in bacteria – depends on complexes formed from the two classes of J-proteins. Further investigation revealed that in humans, J-proteins have structural features that ensure they pair up correctly to perform unique activities. Furthermore, Nillegoda et al. suggest that cooperation between J-proteins may have enabled organisms such as humans – which contain over 40 distinct J-proteins – to carry out further specialized protein-folding tasks that do not occur in prokaryotes. Overall, the findings presented by Nillegoda et al. reveal another important layer to protein quality control in eukaryotic cells. The next step is to understand the possible roles of different J-protein complexes play in J-protein associated cellular protein quality control processes such as preventing protein aggregation, refolding or recycling abnormal proteins. This knowledge could ultimately be used to develop treatments for diseases and disorders in which protein aggregates form. DOI: http://dx.doi.org/10.7554/eLife.24560.002

Published

2016

29. Mutant Analysis Reveals Allosteric Regulation of ClpB Disaggregase

Author

Bernd Bukau, Axel Mogk, and Kamila B. Franke

Subjects

0301 basic medicine, Arginine, ATPase, Protein subunit, Hsp104, Allosteric regulation, Mutant, macromolecular substances, AAA+ protein, Biochemistry, Genetics and Molecular Biology (miscellaneous), Biochemistry, 03 medical and health sciences, ATP hydrolysis, ClpB, Molecular Biosciences, protein disaggregation, Molecular Biology, Original Research, biology, arginine finger, Cell biology, 030104 developmental biology, Chaperone (protein), biology.protein, CLPB

Abstract

The members of the hexameric AAA+ disaggregase of E. coli and S. cerevisiae, ClpB and Hsp104, cooperate with the Hsp70 chaperone system in the solubilization of aggregated proteins. Aggregate solubilization relies on a substrate threading activity of ClpB/Hsp104 fueled by ATP hydrolysis in both ATPase rings (AAA-1, AAA-2). ClpB/Hsp104 ATPase activity is controlled by the M-domains, which associate to the AAA-1 ring to downregulate ATP hydrolysis. Keeping M-domains displaced from the AAA-1 ring by association with Hsp70 increases ATPase activity due to enhanced communication between protomers. This communication involves conserved arginine fingers. The control of ClpB/Hsp104 activity is crucial, as hyperactive mutants with permanently dissociated M-domains exhibit cellular toxicity. Here, we analyzed AAA-1 inter-ring communication in relation to the M-domain mediated ATPase regulation, by subjecting a conserved residue of the AAA1 domain subunit interface of ClpB (A328) to mutational analysis. While all A328X mutants have reduced disaggregation activities, their ATPase activities strongly differed. ClpB-A328I/L mutants have reduced ATPase activity and, when combined with the hyperactive ClpB-K476C M-domain mutation, suppress cellular toxicity. This underlines that ClpB ATPase activation by M-domain dissociation relies on increased subunit communication. The ClpB-A328V mutant in contrast has very high ATPase activity and exhibits cellular toxicity on its own, qualifying it as novel hyperactive ClpB mutant. ClpB-A328V hyperactivity is, however, different from that of M-domain mutants as M-domains stay associated with the AAA-1 ring. The high ATPase activity of ClpB-A328V primarily relies on the AAA-2 ring and correlates with distinct conformational changes in the AAA-2 catalytic site. These findings characterize the subunit interface residue A328 as crucial regulatory element to control ATP hydrolysis in both AAA rings.

Published

2016

30. Toxic Activation of an AAA+ Protease by the Antibacterial Drug Cyclomarin A

Author

Bernd Bukau, Sebastian Gremer, Axel Mogk, Gabrielle Taylor, Michael Maurer, Daniela Linder, Jasmin Jäger, Matthias P. Mayer, Felix Gloge, Laura Le Breton, Kamila B. Franke, Eilika Weber-Ban, and Marta Carroni

Subjects

Models, Molecular, Proteases, Programmed cell death, medicine.medical_treatment, ATPase, Clinical Biochemistry, Molecular Conformation, Protein degradation, 01 natural sciences, Biochemistry, Mycobacterium tuberculosis, Chimera (genetics), Drug Discovery, Escherichia coli, medicine, Molecular Biology, Pharmacology, Protease, biology, 010405 organic chemistry, Signal transducing adaptor protein, biology.organism_classification, Anti-Bacterial Agents, 0104 chemical sciences, biology.protein, ATPases Associated with Diverse Cellular Activities, Molecular Medicine, Oligopeptides

Abstract

ATP-driven bacterial AAA+ proteases have been recognized as drug targets. They possess an AAA+ protein (e.g., ClpC), which threads substrate proteins into an associated peptidase (e.g., ClpP). ATPase activity and substrate selection of AAA+ proteins are regulated by adapter proteins that bind to regulatory domains, such as the N-terminal domain (NTD). The antibacterial peptide Cyclomarin A (CymA) kills Mycobacterium tuberculosis cells by binding to the NTD of ClpC. How CymA affects ClpC function is unknown. Here, we reveal the mechanism of CymA-induced toxicity. We engineered a CymA-sensitized ClpC chimera and show that CymA activates ATPase and proteolytic activities. CymA mimics adapter binding and enables autonomous protein degradation by ClpC/ClpP with relaxed substrate selectivity. We reconstitute CymA toxicity in E. coli cells expressing engineered ClpC and ClpP, demonstrating that gain of uncontrolled proteolytic activity causes cell death. This validates drug-induced overriding of AAA+ protease activity control as effective antibacterial strategy.

Published

2019

31. Dynamic enzyme docking to the ribosome coordinates N-terminal processing with polypeptide folding

Author

Rebecca C. Wade, Michael Martinez, Günter Kramer, Arzu Sandikci, Bernd Bukau, Felix Gloge, and Matthias P. Mayer

Subjects

Models, Molecular, Ribosomal Proteins, Protein Folding, Protein Conformation, Molecular Sequence Data, Sequence alignment, Ribosome, Amidohydrolases, Peptide deformylase, Protein structure, Structural Biology, Protein Interaction Mapping, Amino Acid Sequence, Binding site, Molecular Biology, Peptide sequence, Conserved Sequence, Sequence Homology, Amino Acid, biology, Chemistry, Escherichia coli Proteins, Protein Structure, Tertiary, Molecular Docking Simulation, Kinetics, Biochemistry, Chaperone (protein), biology.protein, Biophysics, Protein folding, Protein Processing, Post-Translational, Ribosomes, Sequence Alignment

Abstract

Newly synthesized polypeptides undergo various cotranslational maturation steps, including N-terminal enzymatic processing, chaperone-assisted folding and membrane targeting, but the spatial and temporal coordination of these steps is unclear. We show that Escherichia coli methionine aminopeptidase (MAP) associates with ribosomes through a charged loop that is crucial for nascent-chain processing and cell viability. MAP competes with peptide deformylase (PDF), the first enzyme to act on nascent chains, for binding sites at the ribosomal tunnel exit. PDF has extremely fast association and dissociation kinetics, which allows it to frequently sample ribosomes and ensure the processing of nascent chains after their emergence. Premature recruitment of the chaperone trigger factor, or polypeptide folding, negatively affect processing efficiency. Thus, the fast ribosome association kinetics of PDF and MAP are crucial for the temporal separation of nascent-chain processing from later maturation events, including chaperone recruitment and folding.

Published

2013

32. Mechanism of Hsp104/ClpB inhibition by prion curing Guanidinium hydrochloride

Author

Bernd Bukau, Yuki Oguchi, Fabian Seyffer, Axel Mogk, and Eva Kummer

Subjects

Protein Denaturation, Saccharomyces cerevisiae Proteins, Prions, Hsp104, Endopeptidase Clp, ATPase, Saccharomyces cerevisiae, Biophysics, macromolecular substances, Plasma protein binding, Biology, medicine.disease_cause, Biochemistry, Protein Refolding, Hsp70, Adenosine Triphosphate, AAA protein, Genes, Reporter, Structural Biology, ClpB, Escherichia coli, Genetics, medicine, HSP70 Heat-Shock Proteins, Protein Interaction Domains and Motifs, Binding site, Luciferases, Molecular Biology, Guanidine, Heat-Shock Proteins, Binding Sites, Escherichia coli Proteins, Cell Biology, biology.organism_classification, Recombinant Proteins, Protein disaggregation, Microscopy, Fluorescence, Prion, biology.protein, CLPB, Protein Binding

Abstract

The Saccharomyces cerevisiae AAA+ protein Hsp104 and its Escherichia coli counterpart ClpB cooperate with Hsp70 chaperones to refold aggregated proteins and fragment prion fibrils. Hsp104/ClpB activity is regulated by interaction of the M-domain with the first ATPase domain (AAA-1), controlling ATP turnover and Hsp70 cooperation. Guanidinium hydrochloride (GdnHCl) inhibits Hsp104/ClpB activity, leading to prion curing. We show that GdnHCl binding exerts dual effects on Hsp104/ClpB. First, GdnHCl strengthens M-domain/AAA-1 interaction, stabilizing Hsp104/ClpB in a repressed conformation and abrogating Hsp70 cooperation. Second, GdnHCl inhibits continuous ATP turnover by AAA-1. These findings provide the mechanistic basis for prion curing by GdnHCl.

Published

2013

33. A tightly regulated molecular toggle controls AAA+ disaggregase

Author

Fabian Seyffer, Benjamin Anstett, Yuki Oguchi, Eva Kummer, Rebecca C. Wade, Regina Zahn, Bernd Bukau, Axel Mogk, and Mykhaylo Berynskyy

Subjects

Mutation, biology, Protein Conformation, Escherichia coli Proteins, Endopeptidase Clp, ATPase, Molecular Sequence Data, medicine.disease_cause, Cell biology, Protein structure, Structural Biology, Chaperone (protein), biology.protein, Biophysics, medicine, Amino Acid Sequence, CLPB, Molecular Biology, Escherichia coli, Peptide sequence, Heat-Shock Proteins, Molecular Chaperones

Abstract

The ring-forming AAA+ protein ClpB cooperates with the DnaK chaperone system to refold aggregated proteins in Escherichia coli. The M domain, a ClpB-specific coiled-coil structure with two wings, motif 1 and motif 2, is essential to disaggregation, but the positioning and mechanistic role of M domains in ClpB hexamers remain unresolved. We show that M domains nestle at the ClpB ring surface, with both M-domain motifs contacting the first ATPase domain (AAA-1). Both wings contribute to maintaining a repressed ClpB activity state. Motif 2 docks intramolecularly to AAA-1 to regulate ClpB unfolding power, and motif 1 contacts a neighboring AAA-1 domain. Mutations that stabilize motif 2 docking repress ClpB, whereas destabilization leads to derepressed ClpB activity with greater unfolding power that is toxic in vivo. Our results underline the vital nature of tight ClpB activity control and elucidate a regulated M-domain toggle control mechanism.

Published

2012

34. Concerted Action of the Ribosome and the Associated Chaperone Trigger Factor Confines Nascent Polypeptide Folding

Author

Anja Hoffmann, Günter Kramer, Annemarie H. Becker, Bernd Bukau, Elke Deuerling, and Beate Zachmann-Brand

Subjects

Peptidylprolyl isomerase, Protease, biology, Trigger factor, medicine.medical_treatment, Cell Biology, Ribosome, Protein structure, Biochemistry, ddc:570, Chaperone (protein), biology.protein, medicine, Biophysics, Protein biosynthesis, Protein folding, Molecular Biology

Abstract

How nascent polypeptides emerging from ribosomes fold into functional structures is poorly understood. Here, we monitor disulfide bond formation, protease resistance, and enzymatic activity in nascent polypeptides to show that in close proximity to the ribosome, conformational space and kinetics of folding are restricted. Folding constraints decrease incrementally with distance from the ribosome surface. Upon ribosome binding, the chaperone Trigger Factor counters folding also of longer nascent chains, to extents varying between different chain segments. Trigger Factor even binds and unfolds pre-existing folded structures, the unfolding activity being limited by the thermodynamic stability of nascent chains. Folding retardation and unfolding activities are not shared by the DnaK chaperone assisting later folding steps. These ribosome- and Trigger Factor-specific activities together constitute an efficient mechanism to prevent or even revert premature folding, effectively limiting misfolded intermediates during protein synthesis.

Published

2012

35. Structural analysis of a signal peptide inside the ribosome tunnel by DNP MAS NMR

Author

W. Trent Franks, Kristina Döring, Nandhakishore Rajagopalan, Günter Kramer, Bernd Bukau, Arne Linden, Michel-Andreas Geiger, Sascha Lange, Barth-Jan van Rossum, and Hartmut Oschkinat

Subjects

0301 basic medicine, Signal peptide, musculoskeletal diseases, Protein structure, dynamic nuclear polarisation, MAS NMR, signal peptide, co-translational folding, ribosome, chemical and pharmacologic phenomena, Protein Sorting Signals, 010402 general chemistry, 01 natural sciences, Ribosome, 03 medical and health sciences, Recognition sequence, Ribosomal protein, Amino Acid Sequence, Signal recognition particle receptor, Research Articles, Signal recognition particle, Multidisciplinary, biology, fungi, SciAdv r-articles, Cell Biology, Magnetic Resonance Imaging, Recombinant Proteins, 3. Good health, 0104 chemical sciences, Transmembrane domain, 030104 developmental biology, DsbA, Biochemistry, Biophysics, biology.protein, lipids (amino acids, peptides, and proteins), Ribosomes, hormones, hormone substitutes, and hormone antagonists, Research Article

Abstract

DNP-enhanced MAS NMR reveals extended conformations for the DsbA signal peptide within the ribosome exit tunnel., Proteins are synthesized in cells by ribosomes and, in parallel, prepared for folding or targeting. While ribosomal protein synthesis is progressing, the nascent chain exposes amino-terminal signal sequences or transmembrane domains that mediate interactions with specific interaction partners, such as the signal recognition particle (SRP), the SecA–adenosine triphosphatase, or the trigger factor. These binding events can set the course for folding in the cytoplasm and translocation across or insertion into membranes. A distinction of the respective pathways depends largely on the hydrophobicity of the recognition sequence. Hydrophobic transmembrane domains stabilize SRP binding, whereas less hydrophobic signal sequences, typical for periplasmic and outer membrane proteins, stimulate SecA binding and disfavor SRP interactions. In this context, the formation of helical structures of signal peptides within the ribosome was considered to be an important factor. We applied dynamic nuclear polarization magic-angle spinning nuclear magnetic resonance to investigate the conformational states of the disulfide oxidoreductase A (DsbA) signal peptide stalled within the exit tunnel of the ribosome. Our results suggest that the nascent chain comprising the DsbA signal sequence adopts an extended structure in the ribosome with only minor populations of helical structure.

Published

2016

36. Translation suppression promotes stress granule formation and cell survival in response to cold shock

Author

Valeria Cherkasova, Bernd Bukau, Sarah Hofmann, Peter Bankhead, and Georg Stoecklin

Subjects

Cell Physiology, Saccharomyces cerevisiae Proteins, Cell Survival, Eukaryotic Initiation Factor-3, Saccharomyces cerevisiae, Eukaryotic Initiation Factor-2, Biology, Protein Serine-Threonine Kinases, Cytoplasmic Granules, Poly(A)-Binding Proteins, Cell Line, Mice, Stress granule, Poly(A)-binding protein, Chlorocebus aethiops, medicine, Protein biosynthesis, Animals, Humans, Phosphorylation, Molecular Biology, Cold-Shock Response, TOR Serine-Threonine Kinases, Adenylate Kinase, Translation (biology), Cell Biology, Articles, biology.organism_classification, Molecular biology, Cell biology, Cold shock response, Enzyme Activation, Kinetics, Protein Transport, Cell culture, Shock (circulatory), Polyribosomes, Protein Biosynthesis, biology.protein, medicine.symptom, Energy Metabolism, Protein Processing, Post-Translational

Abstract

Cells respond to stress by inhibition of protein synthesis and subsequent assembly of stress granules (SGs). Cold shock is identified as a novel trigger of SG assembly in yeast and mammals. Cells actively suppress protein synthesis by parallel pathways to induce SG formation and ensure cellular survival at low temperatures., Cells respond to different types of stress by inhibition of protein synthesis and subsequent assembly of stress granules (SGs), cytoplasmic aggregates that contain stalled translation preinitiation complexes. Global translation is regulated through the translation initiation factor eukaryotic initiation factor 2α (eIF2α) and the mTOR pathway. Here we identify cold shock as a novel trigger of SG assembly in yeast and mammals. Whereas cold shock–induced SGs take hours to form, they dissolve within minutes when cells are returned to optimal growth temperatures. Cold shock causes eIF2α phosphorylation through the kinase PERK in mammalian cells, yet this pathway is not alone responsible for translation arrest and SG formation. In addition, cold shock leads to reduced mitochondrial function, energy depletion, concomitant activation of AMP-activated protein kinase (AMPK), and inhibition of mTOR signaling. Compound C, a pharmacological inhibitor of AMPK, prevents the formation of SGs and strongly reduces cellular survival in a translation-dependent manner. Our results demonstrate that cells actively suppress protein synthesis by parallel pathways, which induce SG formation and ensure cellular survival during hypothermia.

Published

2012

37. Selective Ribosome Profiling Reveals the Cotranslational Chaperone Action of Trigger Factor In Vivo

Author

Günter Kramer, Bernd Bukau, Felix Gloge, Arzu Sandikci, Eugene Oh, Robert J. Nichols, Athanasios Typas, Carol A. Gross, Rachna Chaba, Jonathan S. Weissman, Annemarie H. Becker, and Damon Huber

Subjects

Cytoplasm, Molecular Sequence Data, Ribosome, Article, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, 0302 clinical medicine, Escherichia coli, Protein biosynthesis, Ribosome profiling, 030304 developmental biology, Peptidylprolyl isomerase, 0303 health sciences, biology, Biochemistry, Genetics and Molecular Biology(all), Escherichia coli Proteins, Membrane Proteins, Peptidylprolyl Isomerase, Transport protein, Cell biology, Protein Transport, Biochemistry, Membrane protein, Protein Biosynthesis, Chaperone (protein), biology.protein, Bacterial outer membrane, Ribosomes, 030217 neurology & neurosurgery, Molecular Chaperones

Abstract

SummaryAs nascent polypeptides exit ribosomes, they are engaged by a series of processing, targeting, and folding factors. Here, we present a selective ribosome profiling strategy that enables global monitoring of when these factors engage polypeptides in the complex cellular environment. Studies of the Escherichia coli chaperone trigger factor (TF) reveal that, though TF can interact with many polypeptides, β-barrel outer-membrane proteins are the most prominent substrates. Loss of TF leads to broad outer-membrane defects and premature, cotranslational protein translocation. Whereas in vitro studies suggested that TF is prebound to ribosomes waiting for polypeptides to emerge from the exit channel, we find that in vivo TF engages ribosomes only after ∼100 amino acids are translated. Moreover, excess TF interferes with cotranslational removal of the N-terminal formyl methionine. Our studies support a triaging model in which proper protein biogenesis relies on the fine-tuned, sequential engagement of processing, targeting, and folding factors.PaperClip

Published

2011

38. The ribosome as a platform for co-translational processing, folding and targeting of newly synthesized proteins

Author

Günter Kramer, Bernd Bukau, Nenad Ban, and Daniel Boehringer

Subjects

Models, Molecular, Ribosomal Proteins, Protein Folding, Peptidyl transferase, Protein Conformation, Biology, Protein degradation, medicine.disease_cause, Ribosome, Protein Structure, Secondary, 03 medical and health sciences, Protein structure, Structural Biology, Protein targeting, medicine, Ribosome profiling, Molecular Biology, 030304 developmental biology, 0303 health sciences, 030302 biochemistry & molecular biology, Cell biology, Protein Biosynthesis, biology.protein, Protein folding, Peptides, Eukaryotic Ribosome, Ribosomes, Molecular Chaperones, Protein Binding

Abstract

The early events in the life of newly synthesized proteins in the cellular environment are remarkably complex. Concurrently with their synthesis by the ribosome, nascent polypeptides are subjected to enzymatic processing, chaperone-assisted folding or targeting to translocation pores at membranes. The ribosome itself has a key role in these different tasks and governs the interplay between the various factors involved. Indeed, the ribosome serves as a platform for the spatially and temporally regulated association of enzymes, targeting factors and chaperones that act upon the nascent polypeptides emerging from the exit tunnel. Furthermore, the ribosome provides opportunities to coordinate the protein-synthesis activity of its peptidyl transferase center with the protein targeting and folding processes. Here we review the early co-translational events involving the ribosome that guide cytosolic proteins to their native state.

Published

2009

39. Insights into the structural dynamics of the Hsp110–Hsp70 interaction reveal the mechanism for nucleotide exchange activity

Author

Bernd Bukau, Jocelyne Fiaux, Claes Andréasson, Heike Rampelt, and Silke Druffel-Augustin

Subjects

Saccharomyces cerevisiae Proteins, Mitochondrial Membrane Transport Proteins, DNA-binding protein, Nucleotide exchange factor, Mitochondrial membrane transport protein, Heat shock protein, HSP70 Heat-Shock Proteins, Protein Interaction Domains and Motifs, Nucleotide, HSP110 Heat-Shock Proteins, Binding site, Heat-Shock Proteins, Adenosine Triphosphatases, chemistry.chemical_classification, Binding Sites, Multidisciplinary, biology, Nucleotides, Membrane transport protein, Deuterium Exchange Measurement, Membrane Transport Proteins, Biological Sciences, DNA-Binding Proteins, chemistry, Biochemistry, Chaperone (protein), biology.protein, Biophysics, Molecular Chaperones, Transcription Factors

Abstract

Hsp110 proteins are relatives of canonical Hsp70 chaperones and are expressed abundantly in the eukaryotic cytosol. Recently, it has become clear that Hsp110 proteins are essential nucleotide exchange factors (NEFs) for Hsp70 chaperones. Here, we report the architecture of the complex between the yeast Hsp110, Sse1, and its cognate Hsp70 partner, Ssa1, as revealed by hydrogen–deuterium exchange analysis and site-specific cross-linking. The two nucleotide-binding domains (NBDs) of Sse1 and Ssa1 are positioned to face each other and form extensive contacts between opposite lobes of their NBDs. A second contact with the periphery of the Ssa1 NBD lobe II is likely mediated via the protruding C-terminal α-helical subdomain of Sse1. To address the mechanism of catalyzed nucleotide exchange, we have compared the hydrogen exchange characteristics of the Ssa1 NBD in complex with either Sse1 or the yeast homologs of the NEFs HspBP1 and Bag-1. We find that Sse1 exploits a Bag-1-like mechanism to catalyze nucleotide release, which involves opening of the Ssa1 NBD by tilting lobe II. Thus, Hsp110 proteins use a unique binding mode to catalyze nucleotide release from Hsp70s by a functionally convergent mechanism.

Published

2008

40. Conserved residues in the N‐domain of the AAA+ chaperone ClpA regulate substrate recognition and unfolding

Author

Axel Mogk, Janine Kirstein, Sukhdeep Kaur. Spall, David A. Dougan, Bernd Bukau, Annette H. Erbse, Kornelius Zeth, Kaye N. Truscott, Kürşad Turgay, and Judith N. Wagner

Subjects

Protein Denaturation, Protein Folding, ATPase, Amino Acid Motifs, Molecular Sequence Data, Protein degradation, Random hexamer, Arginine, Biochemistry, Substrate Specificity, Conserved sequence, Protein structure, Escherichia coli, Amino Acid Sequence, Molecular Biology, Peptide sequence, Conserved Sequence, Heat-Shock Proteins, biology, Escherichia coli Proteins, Endopeptidase Clp, Cell Biology, Protein Structure, Tertiary, Amino Acid Substitution, Chaperone (protein), Mutation, biology.protein, Protein folding, Molecular Chaperones

Abstract

Protein degradation in the cytosol of Escherichia coli is carried out by a variety of different proteolytic machines, including ClpAP. The ClpA component is a hexameric AAA+ (ATPase associated with various cellular activities) chaperone that utilizes the energy of ATP to control substrate recognition and unfolding. The precise role of the N-domains of ClpA in this process, however, remains elusive. Here, we have analysed the role of five highly conserved basic residues in the N-domain of ClpA by monitoring the binding, unfolding and degradation of several different substrates, including short unstructured peptides, tagged and untagged proteins. Interestingly, mutation of three of these basic residues within the N-domain of ClpA (H94, R86 and R100) did not alter substrate degradation. In contrast mutation of two conserved arginine residues (R90 and R131), flanking a putative peptide-binding groove within the N-domain of ClpA, specifically compromised the ability of ClpA to unfold and degrade selected substrates but did not prevent substrate recognition, ClpS-mediated substrate delivery or ClpP binding. In contrast, a highly conserved tyrosine residue lining the central pore of the ClpA hexamer was essential for the degradation of all substrate types analysed, including both folded and unstructured proteins. Taken together, these data suggest that ClpA utilizes two structural elements, one in the N-domain and the other in the pore of the hexamer, both of which are required for efficient unfolding of some protein substrates.

Published

2008

41. The N-end rule pathway for regulated proteolysis: prokaryotic and eukaryotic strategies

Author

Axel Mogk, Ronny Schmidt, and Bernd Bukau

Subjects

Proteasome Endopeptidase Complex, Proteolysis, medicine.medical_treatment, N-end rule, Biology, Aminopeptidases, Ubiquitin, medicine, Animals, Methionyl Aminopeptidases, Amino Acid Sequence, Binding site, Peptide sequence, Protease, medicine.diagnostic_test, Escherichia coli Proteins, Signal transducing adaptor protein, Endopeptidase Clp, Cell Biology, Neoplasm Proteins, Eukaryotic Cells, Prokaryotic Cells, Proteasome, Biochemistry, biology.protein, Carrier Proteins

Abstract

The N-end rule states that the half-life of a protein is determined by the nature of its N-terminal residue. This fundamental principle of regulated proteolysis is conserved from bacteria to mammals. Although prokaryotes and eukaryotes employ distinct proteolytic machineries for degradation of N-end rule substrates, recent findings indicate that they share common principles of substrate recognition. In eukaryotes substrate recognition is mediated by N-recognins, a class of E3 ligases that labels N-end rule substrates via covalent linkage to ubiquitin, allowing the subsequent substrate delivery to the 26S proteasome. In bacteria, the adaptor protein ClpS exhibits homology to the substrate binding site of N-recognin. ClpS binds to the destabilizing N-termini of N-end rule substrates and directly transfers them to the ClpAP protease.

Published

2007

42. M Domains Couple the ClpB Threading Motor with the DnaK Chaperone Activity

Author

Jimena Weibezahn, Regina Zahn, Tobias Haslberger, Bernd Bukau, Francis T.F. Tsai, Axel Mogk, and Sukyeong Lee

Subjects

Models, Molecular, Endopeptidase Clp, Molecular Sequence Data, Protein Structure, Secondary, Adenosine Triphosphate, Protein structure, Bacterial Proteins, Heat shock protein, Escherichia coli, HSP70 Heat-Shock Proteins, Amino Acid Sequence, Protein Structure, Quaternary, Molecular Biology, Heat-Shock Proteins, Adenosine Triphosphatases, Sequence Homology, Amino Acid, biology, Escherichia coli Proteins, Molecular Motor Proteins, Thermus thermophilus, Cell Biology, Translocon, biology.organism_classification, Protein Structure, Tertiary, Biochemistry, Chaperone (protein), Mutagenesis, Site-Directed, biology.protein, Biophysics, Threading (protein sequence), CLPB, Molecular Chaperones

Abstract

The AAA(+) chaperone ClpB mediates the reactivation of aggregated proteins in cooperation with the DnaK chaperone system. ClpB consists of two AAA domains that drive the ATP-dependent threading of substrates through a central translocation channel. Its unique middle (M) domain forms a coiled-coil structure that laterally protrudes from the ClpB ring and is essential for aggregate solubilization. Here, we demonstrate that the conserved helix 3 of the M domain is specifically required for the DnaK-dependent shuffling of aggregated proteins, but not of soluble denatured substrates, to the pore entrance of the ClpB translocation channel. Helix 3 exhibits nucleotide-driven conformational changes possibly involving a transition between folded and unfolded states. This molecular switch controls the ClpB ATPase cycle by contacting the first ATPase domain and establishes the M domain as a regulatory device that acts in the disaggregation process by coupling the threading motor of ClpB with the DnaK chaperone activity.

Published

2007

43. Pathways of allosteric regulation in Hsp70 chaperones

Author

Bernd Bukau, Markus Vogel, Rainer Schlecht, Matthias P. Mayer, and Roman Kityk

Subjects

Allosteric regulation, Mutant, General Physics and Astronomy, Article, General Biochemistry, Genetics and Molecular Biology, chemistry.chemical_compound, Adenosine Triphosphate, Allosteric Regulation, ATP hydrolysis, Escherichia coli, HSP70 Heat-Shock Proteins, Binding site, Adenosine Triphosphatases, Binding Sites, Multidisciplinary, biology, Circular Dichroism, Escherichia coli Proteins, General Chemistry, Allosteric enzyme, chemistry, Biochemistry, Mutagenesis, Site-Directed, biology.protein, Biophysics, Protein folding, Signal transduction, Adenosine triphosphate

Abstract

Central to the protein folding activity of Hsp70 chaperones is their ability to interact with protein substrates in an ATP-controlled manner, which relies on allosteric regulation between their nucleotide-binding (NBD) and substrate-binding domains (SBD). Here we dissect this mechanism by analysing mutant variants of the Escherichia coli Hsp70 DnaK blocked at distinct steps of allosteric communication. We show that the SBD inhibits ATPase activity by interacting with the NBD through a highly conserved hydrogen bond network, and define the signal transduction pathway that allows bound substrates to trigger ATP hydrolysis. We identify variants deficient in only one direction of allosteric control and demonstrate that ATP-induced substrate release is more important for chaperone activity than substrate-stimulated ATP hydrolysis. These findings provide evidence of an unexpected dichotomic allostery mechanism in Hsp70 chaperones and provide the basis for a comprehensive mechanical model of allostery in Hsp70s., Hsp70 chaperones are essential for cellular proteostasis, and their function depends on allosteric communication between their nucleotide- and substrate-binding domains. Here, Kityk et al. provide a mechanical model of allostery and demonstrate that ATP-induced substrate release is more important for chaperone activity than substrate-stimulated ATP hydrolysis.

Published

2015

44. Systemic control of protein synthesis through sequestration of translation and ribosome biogenesis factors during severe heat stress

Author

Yevhen Vainshtein, Axel Mogk, Michael Knop, Christine Gläßer, Cyril Mongis, Tomas Grousl, Günter Kramer, Patrick Theer, Georg Stoecklin, Bernd Bukau, and Valeria Cherkasov

Subjects

Proteomics, Cytoplasm, Saccharomyces cerevisiae Proteins, Biophysics, Ribosome biogenesis, Saccharomyces cerevisiae, Biochemistry, Ribosome, Stress granule, Structural Biology, Genetics, Protein biosynthesis, Initiation factor, RNA, Messenger, Molecular Biology, Organelle Biogenesis, biology, Cell Biology, Transport protein, Cell biology, Protein Transport, Solubility, Chaperone (protein), biology.protein, Organelle biogenesis, Ribosomes, Heat-Shock Response

Abstract

Environmental stress causes the sequestration of proteins into insoluble deposits including cytoplasmic stress granules (SGs), containing mRNA and a variety of translation factors. Here we systematically identified proteins sequestered in Saccharomyces cerevisiae at 46 °C by a SG co-localization screen and proteomic analysis of insoluble protein fractions. We identified novel SG components including essential aminoacyl-tRNA synthetases. Moreover, we discovered nucleus-associated deposits containing ribosome biogenesis factors. Our study suggests downregulation of cytosolic protein synthesis and nuclear ribosome production at multiple levels through heat shock induced protein sequestrations.

Published

2015

45. Crucial HSP70 co-chaperone complex unlocks metazoan protein disaggregation

Author

Xuechao Gao, Matthias P. Mayer, Janine Kirstein, Bernd Bukau, Kristin Arnsburg, Florian Stengel, Antonia Stank, Ruedi Aebersold, Mykhaylo Berynskyy, Annika Scior, Rebecca C. Wade, Anna Szlachcic, D. Lys Guilbride, Nadinath B. Nillegoda, and Richard I. Morimoto

Subjects

Models, Molecular, Protein subunit, Static Electricity, Plasma protein binding, Protein aggregation, Protein Aggregation, Pathological, Nucleotide exchange factor, Chaperones, Computational models, Protein aggregation, Protein Aggregates, 03 medical and health sciences, 0302 clinical medicine, Protein structure, ddc:570, Animals, Humans, HSP70 Heat-Shock Proteins, HSP110 Heat-Shock Proteins, Caenorhabditis elegans, 030304 developmental biology, 0303 health sciences, Multidisciplinary, biology, biology.organism_classification, Protein Structure, Tertiary, Cell biology, Co-chaperone, Biochemistry, Chaperone (protein), biology.protein, 030217 neurology & neurosurgery, Protein Binding

Abstract

Protein aggregates are the hallmark of stressed and ageing cells, and characterize several pathophysiological states1, 2. Healthy metazoan cells effectively eliminate intracellular protein aggregates3, 4, indicating that efficient disaggregation and/or degradation mechanisms exist. However, metazoans lack the key heat-shock protein disaggregase HSP100 of non-metazoan HSP70-dependent protein disaggregation systems5, 6, and the human HSP70 system alone, even with the crucial HSP110 nucleotide exchange factor, has poor disaggregation activity in vitro4, 7. This unresolved conundrum is central to protein quality control biology. Here we show that synergic cooperation between complexed J-protein co-chaperones of classes A and B unleashes highly efficient protein disaggregation activity in human and nematode HSP70 systems. Metazoan mixed-class J-protein complexes are transient, involve complementary charged regions conserved in the J-domains and carboxy-terminal domains of each J-protein class, and are flexible with respect to subunit composition. Complex formation allows J-proteins to initiate transient higher order chaperone structures involving HSP70 and interacting nucleotide exchange factors. A network of cooperative class A and B J-protein interactions therefore provides the metazoan HSP70 machinery with powerful, flexible, and finely regulatable disaggregase activity and a further level of regulation crucial for cellular protein quality control. published

Published

2015

46. Allosteric Regulation of Hsp70 Chaperones Involves a Conserved Interdomain Linker

Author

Markus Vogel, Bernd Bukau, and Matthias P. Mayer

Subjects

Models, Molecular, ATPase, Molecular Sequence Data, Allosteric regulation, Biochemistry, Allosteric Regulation, ATP hydrolysis, Heat shock protein, HSP70 Heat-Shock Proteins, Amino Acid Sequence, Molecular Biology, Peptide sequence, Adenosine Triphosphatases, chemistry.chemical_classification, Sequence Homology, Amino Acid, biology, Cell Biology, Amino acid, Spectrometry, Fluorescence, chemistry, Chaperone (protein), Mutagenesis, Site-Directed, biology.protein, Biophysics, Linker

Abstract

The 70-kDa heat shock proteins (Hsp70) are essential members of the cellular chaperone machinery that assists protein-folding processes. To perform their functions Hsp70 chaperones toggle between two nucleotide-controlled conformational states. ATP binding to the ATPase domain triggers the transition to the low affinity state of the substrate-binding domain, while substrate binding to the substrate-binding domain in synergism with the action of a J-domain-containing cochaperone stimulates ATP hydrolysis and thereby transition to the high affinity state. Thus, ATPase and substrate-binding domains mutually affect each other through an allosteric control mechanism, the basis of which is largely unknown. In this study we identified two positively charged, surface-exposed residues in the ATPase domain and a negatively charged residue in the linker connecting both domains that are important for interdomain communication. Furthermore, we demonstrate that the linker alone is sufficient to stimulate the ATPase activity, an ability that is lost upon amino acid replacement. The linker therefore is most likely the lever that is wielded by the substrate-binding domain and the cochaperone onto the ATPase domain to induce a conformation favorable for ATP hydrolysis. Based on our results we propose a mechanism of interdomain communication.

Published

2006

47. The C-terminal Domain ofEscherichia coliTrigger Factor Represents the Central Module of Its Chaperone Activity

Author

Anja Hoffmann, Frieder W. Merz, Bernd Bukau, Elke Deuerling, Beate Zachmann-Brand, and Anna Rutkowska

Subjects

Models, Molecular, Protein Folding, Isomerase activity, Protein Conformation, Mutant, medicine.disease_cause, Biochemistry, Ribosome, Cytosol, ddc:570, Escherichia coli, medicine, Ribonuclease T1, Molecular Biology, Binding Sites, biology, Escherichia coli Proteins, C-terminus, Temperature, Cell Biology, Periplasmic space, Peptidylprolyl Isomerase, Protein Structure, Tertiary, Cell biology, Chaperone (protein), Mutation, Hsp33, biology.protein, Peptides, Molecular Chaperones, Protein Binding

Abstract

In bacteria, ribosome-bound Trigger Factor assists the folding of newly synthesized proteins. The N-terminal domain (N) of Trigger Factor mediates ribosome binding, whereas the middle domain (P) harbors peptidyl-prolyl isomerase activity. The function of the C-terminal domain (C) has remained enigmatic due to structural instability in isolation. Here, we have characterized a stabilized version of the C domain (C(S)), designed on the basis of the recently solved atomic structure of Trigger Factor. Strikingly, only the isolated C(S) domain or domain combinations thereof (NC(S), PC(S)) revealed substantial chaperone activity in vitro and in vivo. Furthermore, to disrupt the C domain without affecting the overall Trigger Factor structure, we generated a mutant (Delta53) by deletion of the C-terminal 53 amino acid residues. This truncation caused the complete loss of the chaperone activity of Trigger Factor in vitro and severely impaired its function in vivo. Therefore, we conclude that the chaperone activity of Trigger Factor critically depends on its C-terminal domain as the central structural chaperone module. Intriguingly, a structurally similar module is found in the periplasmic chaperone SurA and in MPN555, a protein of unknown function. We speculate that this conserved module can exist solely or in combination with additional domains to fulfill diverse chaperone functions in the cell.

Published

2006

48. Chaperone network in the yeast cytosol: Hsp110 is revealed as an Hsp70 nucleotide exchange factor

Author

Fernanda Rodriguez, Heather Sadlish, Bernd Bukau, Matthias P. Mayer, and Holger Raviol

Subjects

Protein Denaturation, Protein Folding, Saccharomyces cerevisiae Proteins, Saccharomyces cerevisiae, Article, General Biochemistry, Genetics and Molecular Biology, Nucleotide exchange factor, ATP hydrolysis, Animals, HSP70 Heat-Shock Proteins, HSP110 Heat-Shock Proteins, Molecular Biology, Adenosine Triphosphatases, General Immunology and Microbiology, biology, General Neuroscience, biology.organism_classification, Yeast, Hsp70, Cytosol, Biochemistry, Multiprotein Complexes, Chaperone (protein), biology.protein, Protein folding, Molecular Chaperones

Abstract

The Hsp110 proteins, exclusively found in the eukaryotic cytosol, have significant sequence homology to the Hsp70 molecular chaperone superfamily. Despite this homology and the cellular abundance of these proteins, the precise functional role has remained undefined. Here, we present the intriguing finding that the yeast homologue, Sse1p, acts as an efficient nucleotide exchange factor (NEF) for both yeast cytosolic Hsp70s, Ssa1p and Ssb1p. The mechanism involves formation of a stable nucleotide-sensitive complex, but does not require ATP hydrolysis by Sse1p. The NEF activity of Sse1p stimulates in vitro Ssa1p-mediated refolding of thermally denatured luciferase, and appears to have an essential role in vivo. Overexpression of the only other described cytosolic NEF, Fes1p, can partially compensate for a lethal sse1,2Delta phenotype, however, the cells are sensitive to stress conditions. Furthermore, in the absence of Sse, the in vivo refolding of thermally denatured model proteins is affected. This is the first report of a nucleotide exchange activity for the Hsp110 class of proteins, and provides a key piece in the puzzle of the cellular chaperone network.

Published

2006

49. Allosteric Regulation of Hsp70 Chaperones by a Proline Switch

Author

Bernd Bukau, Matthias P. Mayer, and Markus Vogel

Subjects

Models, Molecular, Proline, Arginine, Protein Conformation, ATPase, Allosteric regulation, Dissociation (chemistry), Adenosine Triphosphate, Protein structure, Allosteric Regulation, Animals, HSP70 Heat-Shock Proteins, Binding site, Molecular Biology, Binding Sites, biology, Hydrogen bond, Tryptophan, Hydrogen Bonding, Cell Biology, Adenosine Diphosphate, Amino Acid Substitution, Biochemistry, Mutagenesis, Site-Directed, biology.protein, Biophysics

Abstract

Crucial to the function of Hsp70 chaperones is the nucleotide-regulated transition between two conformational states, the ATP bound state with high association and dissociation rates for substrates and the ADP bound state with two and three orders of magnitude lower association and dissociation rates. The spontaneous transition between the two states is extremely slow, indicating a high energy barrier for the switch that regulates the transition. Here we provide evidence that a universally conserved proline in the ATPase domain constitutes the switch that assumes alternate conformations in response to ATP binding and hydrolysis. The conformation of the proline, acting through an invariant arginine as relay, determines and stabilizes the opened and closed conformation of the substrate binding domain and thereby regulates the chaperone activity of Hsp70.

Published

2006

50. YfhJ, a molecular adaptor in iron-sulfur cluster formation or a frataxin-like protein?

Author

Annalisa Pastore, Chiara Pastore, Martjin A. Huynen, Vladimir Rybin, Stephen R. Martin, Salvatore Adinolfi, Bernd Bukau, Mathias Mayer, Pastore, C, Adinolfi, S, Huynen, Ma, Rybin, V, Martin, S, Mayer, M, Bukau, B, and Pastore, A

Subjects

Iron-Sulfur Proteins, inorganic chemicals, Energy and redox metabolism [NCMLS 4], Protein Conformation, Bioinformatics, Operon, Iron, Molecular Sequence Data, FE-S CLUSTER, ASSIGNMENT, Iron–sulfur cluster, Winged Helix, SEQUENCE, DNA-binding protein, ISCU, chemistry.chemical_compound, Protein structure, Bacterial Proteins, DOMAIN, Structural Biology, Iron-Binding Proteins, CRYSTAL-STRUCTURE, BIOSYNTHESIS, Amino Acid Sequence, SCAFFOLD PROTEIN, Molecular Biology, biology, FE-S CLUSTER, BINDING PROPERTIES, CRYSTAL-STRUCTURE, SCAFFOLD PROTEIN, CHEMICAL-SHIFT, SEQUENCE, DOMAIN, ISCU, BIOSYNTHESIS, ASSIGNMENT, BINDING PROPERTIES, Small acidic protein, Iron-binding proteins, CHEMICAL-SHIFT, Mitochondrial medicine [IGMD 8], chemistry, Biochemistry, Frataxin, biology.protein, Cellular energy metabolism [UMCN 5.3]

Abstract

Contains fulltext : 51201.pdf (Publisher’s version ) (Closed access) The yfhJ gene is part of the isc operon, which encodes the machinery devoted to assemble iron-sulfur clusters in prokaryotes. Its transcript is a small acidic protein that binds the desulfurase IscS, which is essential in iron-specific metabolic pathways. To understand its cellular role, we have characterized the structure of YfhJ in solution and its interactions with potential cellular partners. It contains a modified winged helix motif, usually present in DNA binding proteins, and is able to bind iron cations. The IscS interaction surface is the same as that involved in iron binding. This observation and the pattern of conservation through species strongly suggest that YfhJ is a molecular adaptor that is able to modulate the function of IscS in iron-sulfur cluster formation. The remarkable similarity between the in vitro behavior of YfhJ and that of the protein frataxin also suggests new hypotheses regarding the functional role of both proteins.

Published

2006